0028/4: RIO BLANCO Small Hydroelectric Project, Honduras
The project activity contemplates the production of clean hydroelectric power that will contribute to reduce the Honduran imported petroleum bill and reduce CO2 emissions, which would had occurred otherwise, in the absence of this project.
0031/1: Methane capture and combustion from swine manure treatment for Corneche and Los Guindos, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of ambient temperature anaerobic digesters for swine manure treatment at Corneche and Los Guindos.
0031/2: Methane capture and combustion from swine manure treatment for Corneche and Los Guindos, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of ambient temperature anaerobic digesters for swine manure treatment at Corneche and Los Guindos.
0031/3: Methane capture and combustion from swine manure treatment for Corneche and Los Guindos, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of ambient temperature anaerobic digesters for swine manure treatment at Corneche and Los Guindos.
0032/1: Methane capture and combustion from swine manure treatment for Peralillo, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0032/2: Methane capture and combustion from swine manure treatment for Peralillo, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0032/3: Methane capture and combustion from swine manure treatment for Peralillo, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0033/1: Methane capture and combustion from swine manure treatment for Pocillas and La Estrella, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0033/2: Methane capture and combustion from swine manure treatment for Pocillas and La Estrella, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0033/3: Methane capture and combustion from swine manure treatment for Pocillas and La Estrella, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an ambient temperature anaerobic digester with an enclosed flare followed by an activated sludge treatment plant.
0058/1: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0058/2: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0058/3: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0058/4: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0058/5: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0058/6: Biomass in Rajasthan - Electricity generation from mustard crop residues, India
The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 7.8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid with the balance sold to third parties (large industrial customers).
0071/1: Nanjing Tianjingwa Landfill Gas to Electricity Project, China
The purpose of the project activity is to utilize landfill gas from a nearby municipal landfill for effective generation of electricity for supply to the grid. The project activity will help in reducing the Green House Gases (GHG) emitted during use of mainly coal at grid-connected power plants and conserve the natural resource.
0071/2: Nanjing Tianjingwa Landfill Gas to Electricity Project , China
The purpose of the project activity is to utilize landfill gas from a nearby municipal landfill for effective generation of electricity for supply to the grid. The project activity will help in reducing the Green House Gases (GHG) emitted during use of mainly coal at grid-connected power plants and conserve the natural resource.
0071/3: Nanjing Tianjingwa Landfill Gas to Electricity Project , China
The purpose of the project activity is to utilize landfill gas from a nearby municipal landfill for effective generation of electricity for supply to the grid. The project activity will help in reducing the Green House Gases (GHG) emitted during use of mainly coal at grid-connected power plants and conserve the natural resource.
0071/4: Nanjing Tianjingwa Landfill Gas to Electricity Project , China
The purpose of the project activity is to utilize landfill gas from a nearby municipal landfill for effective generation of electricity for supply to the grid. The project activity will help in reducing the Green House Gases (GHG) emitted during use of mainly coal at grid-connected power plants and conserve the natural resource.
0071/5: Nanjing Tianjingwa Landfill Gas to Electricity Project , China
The purpose of the project activity is to utilize landfill gas from a nearby municipal landfill for effective generation of electricity for supply to the grid. The project activity will help in reducing the Green House Gases (GHG) emitted during use of mainly coal at grid-connected power plants and conserve the natural resource.
0087/1:20 MW Kabini Hydro Electric Power Project, SKPCL, India
The project involves the implementation of a hydro project on an existing irrigation dam which was constructed in 1975. The installed capacity of the plant is 20 MWel. The dam on the River Kabini was primarily designed to hold monsoon water in order to meet the irrigation requirements of the downstream area during the rest of the year. In this project, the surplus water during the monsoon season, which was previously discharged into the river, is used to generate electricity from renewable sources. During the rest of the year, the plant is designed to operate at a much lower level depend
0087/2: 20 MW Kabini Hydro Electric Power Project, SKPCL, India
The project involves the implementation of a hydro project on an existing irrigation dam which was constructed in 1975. The installed capacity of the plant is 20 MWel. The dam on the River Kabini was primarily designed to hold monsoon water in order to meet the irrigation requirements of the downstream area during the rest of the year. In this project, the surplus water during the monsoon season, which was previously discharged into the river, is used to generate electricity from renewable sources. During the rest of the year, the plant is designed to operate at a much lower level depend
0087/3: 20 MW Kabini Hydro Electric Power Project, SKPCL, India
The project involves the implementation of a hydro project on an existing irrigation dam which was constructed in 1975. The installed capacity of the plant is 20 MWel. The dam on the River Kabini was primarily designed to hold monsoon water in order to meet the irrigation requirements of the downstream area during the rest of the year. In this project, the surplus water during the monsoon season, which was previously discharged into the river, is used to generate electricity from renewable sources. During the rest of the year, the plant is designed to operate at a much lower level depend
0089/1: Vaturu and Wainikasou Hydro Projects, Oceania
The project involves the implementation of 2 hydro power plants The installed capacity of the two plants is 3 and 6,5 MWel respectively, totalling 9,5 MW el. The water used comes from existing bassins or storage systems. The electricity generated will be sold completely to the national grid.
0089/2: Vaturu and Wainikasou Hydro Projects, Oceania
The project involves the implementation of 2 hydro power plants The installed capacity of the two plants is 3 and 6,5 MWel respectively, totalling 9,5 MW el. The water used comes from existing bassins or storage systems. The electricity generated will be sold completely to the national grid.
0095/1: DSL Biomass based Power Project at Pagara, India
The purpose of the project activity is to utilize surplus biomass available in the region for effective generation of electricity for captive use. The project activity will help in reducing the Green House Gases (GHG) emitted during use of diesel in the diesel generator (DG) sets and conserve the natural resource.
0095/2: DSL Biomass based Power Project at Pagara, India
The purpose of the project activity is to utilize surplus biomass available in the region for effective generation of electricity for captive use. The project activity will help in reducing the Green House Gases (GHG) emitted during use of diesel in the diesel generator (DG) sets and conserve the natural resource.
0095/3: DSL Biomass based Power Project at Pagara, India
The purpose of the project activity is to utilize surplus biomass available in the region for effective generation of electricity for captive use. The project activity will help in reducing the Green House Gases (GHG) emitted during use of diesel in the diesel generator (DG) sets and conserve the natural resource.
0095/4: DSL Biomass based Power Project at Pagara, India
The purpose of the project activity is to utilize surplus biomass available in the region for effective generation of electricity for captive use. The project activity will help in reducing the Green House Gases (GHG) emitted during use of diesel in the diesel generator (DG) sets and conserve the natural resource.
0095/5: DSL Biomass based Power Project at Pagara, India
The purpose of the project activity is to utilize surplus biomass available in the region for effective generation of electricity for captive use. The project activity will help in reducing the Green House Gases (GHG) emitted during use of diesel in the diesel generator (DG) sets and conserve the natural resource.
0099/1: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/2: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/3: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/4: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/5: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/6: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/7: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/8: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/9: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/10: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/11: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/12: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/13: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/14: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/15: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/16: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/17: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/18: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/19: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/20: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/21: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/22: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/23: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/24: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/25: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/26: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/27: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/28: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/29: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/30: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/31: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/32: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/33: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/34: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/40: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/41: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/42: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/43: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/44: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/45: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/46: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/47: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/48: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/49: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/50: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/51: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0099/52: N2O Emission Reduction in Onsan, Republic of Korea
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a greenhouse gas (GHG), whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0113/1: JCT Phagwara Small Scale Biomass Project, India
The purpose of the project is to utilize biomass such as rice husk for effective generation and supply of electricity to the textile plant to meet its captive energy demand.
0116/1: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/2: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/3: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/4: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/5: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/6: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/7: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/8: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/9: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/10: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/11: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/12: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/13: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/14: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/15: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/16: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/17: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/18: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/19: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/20: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/21: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/22: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/23: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/24: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/25: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/26: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/27: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/28: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/29: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/30: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/31: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0116/32: N2O Emission Reduction in Paulínia, SP, Brazil
Nitrous oxide (N2O) is a by-product of adipic acid production. It is of low toxicity but is a green house gas, whose GWP is large (GWP=310 in the IPCC 2nd Assessment Report). In this project, Rhodia Polyamide Co. Ltd additionally installed N2O collection and thermal decomposition process equipment to the currently operating adipic acid manufacturing plant.
0151/1: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/2: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/3: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/4: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/5: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/6: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/7: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/8: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/9: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/10: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/11: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/12: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/13:Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/14: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/15: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/15: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/16: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/17: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/18: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/19: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/21: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/22: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0151/23: Quimobásicos HFC Recovery and Decomposition Project , Mexico
The project activity involves the installation of an in-flight argon plasma arc facility to decompose the HFC23 generated as by-product of HCFC 22 production of Quimobásicos S.A. de C.V. at their plant in Moterrey, Mexico. As a brief description of the process, the waste gas stream enters into the plasma torch, which is of segmented design, using argon as plasma gas. The argon plasma is generated by a direct current discharge between a cathode and an anode.
0156/3: CECECAPA Small Hydroelectric Project, Honduras
The project activity contemplates the production of clean hydroelectric power thus a “Hydroelec-tric power project” which is reducing the Honduran imported petroleum bill and reducing the CO2 emissions. The main objective is generating clean energy while operating and maintaining the facility, selling the power to the Empresa Nacional de Energia Electrica (ENEE) through a con-tract with duration of 15 years.
0157/3: Yojoa Small Hydropower Project, Honduras
Yojoa Small Hydropower Project produces electricity using a renewable resource (water), in order to contribute to meet the local power demand. The project consists is a run-off-river renewable hydroelectric generating central which is composed by a regulatory dam, a forebay that will be used to remove any sediment carried by the incoming flow of water, a conducting line operating at gravity, a pressure tank, pressure pipe, powerhouse, a discharge channel and access road.
0164/1: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/2: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/3: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/4:Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/5: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/6: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/7: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/8: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/9: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/10: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/11: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/12: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/13: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/14: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/15: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/16: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0164/17: Bandeirantes Landfill Gas to Energy Project (BLFGE) , Brazil
Bandeirantes Landfill Gas to Energy Project is a project designed to explore the landfill gas produced in Bandeirantes landfill, one of the biggest landfills in Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, Bandeirantes Landfill Gas to Energy Project was the designed solution created by Biogás.
0165/1: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/2: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/3: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/4: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/5: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/6: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/7: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/8: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/9: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0165/10: ESTRE’s Paulínia Landfill Gas Project (EPLGP). Brazil
The purpose of the project “ESTRE’s Paulínia Landfill Gas Project (EPLGP)” is focused on the capturing and flaring of landfill gas. Landfill gas contents about 50 % of methane which is a significant greenhouse gas. Through flaring of the landfill gas by an active recovery system, methane emissions are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0168/3: BK Energia Itacoatiara Project, Brazil
BK Energia Itacoatiara Project consists of the generation of electricity with a thermoelectric power plant using wood residues from wood processing companies in the city of Itacoatiara, in the State of Amazonas, Brazil. Prior to the project activity, wood waste generated in the production process, were stored in several sawdust and wood residues stockpiles, which represented besides an environmental and safety problem, methane emissions released to the atmosphere.
0168/4: BK Energia Itacoatiara Project, Brazil
BK Energia Itacoatiara Project consists of the generation of electricity with a thermoelectric power plant using wood residues from wood processing companies in the city of Itacoatiara, in the State of Amazonas, Brazil. Prior to the project activity, wood waste generated in the production process, were stored in several sawdust and wood residues stockpiles, which represented besides an environmental and safety problem, methane emissions released to the atmosphere.
0176/1: Meizhou Landfills Gas Recovery and Utilization as Energy, China
The purpose of the project activity is to destroy methane from a nearby municipal landfill by flaring and generation of electricity for supply to the grid.
0176/2: Meizhou Landfills Gas Recovery and Utilization as Energy, China
The purpose of the project activity is to destroy methane from a nearby municipal landfill by flaring and generation of electricity for supply to the grid.
0176/3: Meizhou Landfills Gas Recovery and Utilization as Energy, China
The purpose of the project activity is to destroy methane from a nearby municipal landfill by flaring and generation of electricity for supply to the grid.
0195/1: Rice Husk based Cogeneration project at Shree Bhawani Paper Mills Limited (SBPML), Rae Bareli, Uttar Pradesh, India
The project involves the implementation of a biomass-based co-generation plant. The installed capacity of the plant is 3 MW el. The fuel used is primarily rice husk, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid.
0195/2: Rice Husk based Cogeneration project at Shree Bhawani Paper Mills Limited (SBPML), Rae Bareli, Uttar Pradesh, India
The project involves the implementation of a biomass-based co-generation plant. The installed capacity of the plant is 3 MW el. The fuel used is primarily rice husk, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid.
0195/3: Rice Husk based Cogeneration project at Shree Bhawani Paper Mills Limited (SBPML), Rae Bareli, Uttar Pradesh, India
The project involves the implementation of a biomass-based co-generation plant. The installed capacity of the plant is 3 MW el. The fuel used is primarily rice husk, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid.
0195/4: Rice Husk based Cogeneration project at Shree Bhawani Paper Mills Limited (SBPML), Rae Bareli, Uttar Pradesh, India
The project involves the implementation of a biomass-based co-generation plant. The installed capacity of the plant is 3 MW el. The fuel used is primarily rice husk, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid.
0198/1: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0198/2: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0198/3: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0198/4: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0198/5: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0198/6: San Jacinto Tizate geothermal project, Nicaragua
The project activity involves the construction of a geothermal power plant (GPP) in San Jacinto, Nicaragua with an overall capacity of 66 MWe. The San Jacinto-Tizate field has the potential to provide up to 100 MW of additional power. There is no use of the geothermal heat. The main feature of the project is therefore the electricity production by geothermal steam substituting electricity produced to a high degree by oil fired power plants.
0215/1: Coinbra-Cresciumal Bagasse Cogeneration Project (CCBCP), Brazil
The project consist of the enlargement of existing bagasse-powered cogeneration facilities at Coinbra-Cresciumal Sugar Mill, located in Leme, province of Sao Paulo, Brazil. By that, addi-tional renewable energy generated by the project activity displaces thermal, non-renewable en-ergy generation from the local electricity grid.
0215/2: Coinbra-Cresciumal Bagasse Cogeneration Project (CCBCP), Brazil
The project consist of the enlargement of existing bagasse-powered cogeneration facilities at Coinbra-Cresciumal Sugar Mill, located in Leme, province of Sao Paulo, Brazil. By that, addi-tional renewable energy generated by the project activity displaces thermal, non-renewable en-ergy generation from the local electricity grid.
0218/1: CDM SOLAR COOKER PROJECT Aceh 1, Indonesia
The project activity involves the installation of newly developed solar cookers and heat retention containers for cooking, heating and sterilizing of water and for preserving food. The project is designed to save non sustainable harvested fuel wood and to avoid the emission of greenhouse gases and smoke from traditional cooking and from forest fires, and to improve the living standard of households, promoting health and enabling income generation.
0231/1: CAMIL Itaqui Biomass Electricity Generation Project, Brazil
The project activity involves the implementation of a biomass-based power generation plant using direct combustion boiler technology. The installed capacity of the plant is 4.2 MWel. The used fuel is rice husk residues.
0233/1: Zhangbei Manjing Windfarm Project, China
The objective of the Zhangbei Manjing Windfarm Project is to generate renewable electricity using wind power resources and to sell the generated output to the North China Power Grid on the basis of a power purchase agreement (PPA). The project activity will generate greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from electricity generation by fossil fuel power plants that supply the North China Power Grid.
0233/2: Zhangbei Manjing Windfarm Project, China
The objective of the Zhangbei Manjing Windfarm Project is to generate renewable electricity using wind power resources and to sell the generated output to the North China Power Grid on the basis of a power purchase agreement (PPA). The project activity will generate greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from electricity generation by fossil fuel power plants that supply the North China Power Grid.
0233/3: Zhangbei Manjing Windfarm Project, China
The objective of the Zhangbei Manjing Windfarm Project is to generate renewable electricity using wind power resources and to sell the generated output to the North China Power Grid on the basis of a power purchase agreement (PPA). The project activity will generate greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from electricity generation by fossil fuel power plants that supply the North China Power Grid.
0233/4: Zhangbei Manjing Windfarm Project, China
The objective of the Zhangbei Manjing Windfarm Project is to generate renewable electricity using wind power resources and to sell the generated output to the North China Power Grid on the basis of a power purchase agreement (PPA). The project activity will generate greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from electricity generation by fossil fuel power plants that supply the North China Power Grid.
0235/2: Zacapa Mini Hydro Station Project, Honduras
This project activity of the Finnish CDM/JI Pilot Programme consists of the renovation of installations and equipment of an existing small hydroelectric plant (520 kW) to generate clean energy by utilization of water from the Zacapa river. The plant, located by the Agua Zarca village, jurisdiction of the Municipality of San Pedro Zacapa, Honduras, is a run-off a river type with minimum environmental impact and will provide and sell electricity to the national grid through ENEE (power utility).
0239/3: Wigton Wind Farm Project (WWF), Jamaica
The objective of the project is to implement the first commercial grid connected wind power plant in Jamaica. The project will lead to reduced greenhouse gas emissions because it will be displacing a largely fossil fuel based electricity generating system.
0239/4: Wigton Wind Farm Project (WWF), Jamaica
The objective of the project is to implement the first commercial grid connected wind power plant in Jamaica. The project will lead to reduced greenhouse gas emissions because it will be displacing a largely fossil fuel based electricity generating system.
0254/1: Lepanto Landfill Gas Management Project, Chile
Lepanto Landfill Gas Management Project is a project designed to capture and destroy the me-thane produced by the Lepanto Landfill using an efficient and controlled flaring system. This landfill is located near the locality of Nos, in the metropolitan region of Santiago, Chile. The project has been developed to burn the methane and convert it into carbon dioxide, thus the high global warming potential of methane is avoided. Through this solution, the project pro-ponent found an environmental, social, and financial solution to avoid landfill gas release into the atmosphere.
0256/1: Jilin Tongyu Huaneng 100.05MW Wind Power Project, China
The Jilin Tongyu Huaneng 100.5MW Wind Power Project project is sited within the Tongyu county, Baicheng city, Jilin province in the North-eastern China. The grid-connected renewable power project is to utilize the wind resources for generating renewable electricity to sell into the Jilin Power Grid. The proposed project activity will achieve the greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from the business-as-usual scenario, the electricity generation of those fossil fuel-fired power plants connected into the Jilin Power Grid.
0256/2: Jilin Tongyu Huaneng 100.05MW Wind Power Project, China
The Jilin Tongyu Huaneng 100.5MW Wind Power Project project is sited within the Tongyu county, Baicheng city, Jilin province in the North-eastern China. The grid-connected renewable power project is to utilize the wind resources for generating renewable electricity to sell into the Jilin Power Grid. The proposed project activity will achieve the greenhouse gas (GHG) emission reductions by avoiding CO2 emissions from the business-as-usual scenario, the electricity generation of those fossil fuel-fired power plants connected into the Jilin Power Grid.
0264/1: Waste heat based 7 MW Captive Power Project Godawari Power and Ispat Ltd (GPIL), India
GPIL’s 18 MW Captive Power Plant consists of a 30 TPH Waste Heat Recovery Boiler that utilizes waste heat from sponge iron kilns as energy source, a 70 TPH Fluidised Bed Combustion (FBC) Boiler that uses coal rejects (coal char and coal fines) from sponge iron process as fuel, a common steam header and 2 x 10 MW turbo generator (TG). WHRB was installed by GPIL to improve the energy efficiency of the production process and FBC was installed to avoid the pollution problems associated with disposal of coal rejects as required by pollution control norms.
0264/2: Waste heat based 7 MW Captive Power Project Godawari Power and Ispat Ltd (GPIL), India
GPIL’s 18 MW Captive Power Plant consists of a 30 TPH Waste Heat Recovery Boiler that utilizes waste heat from sponge iron kilns as energy source, a 70 TPH Fluidised Bed Combustion (FBC) Boiler that uses coal rejects (coal char and coal fines) from sponge iron process as fuel, a common steam header and 2 x 10 MW turbo generator (TG). WHRB was installed by GPIL to improve the energy efficiency of the production process and FBC was installed to avoid the pollution problems associated with disposal of coal rejects as required by pollution control norms.
0281/CP1/1: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0281/CP1/2: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0281/CP1/3: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0281/CP2/1: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0281/CP2/2: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0281/CP2/3: 4.5 MW Biomass (Agricultural Residue) Based Power Generation Unit of M/s Matrix Power Pvt. Ltd. (MPPL), India
The purpose of the project activity is to develop and operate a 4.5 MW power plant at Karempudi Village, Guntur district of Andhra Pradesh that would be based on the surplus agricultural residue available in the local villages. The agricultural residues are rice husk, red gram stalks, chilli stalks, cotton stalks, Bengal gram husk and jute. The project activity supplies electricity to the southern grid which is predominantly coal based.
0299/1: Guangdong Nan’ao Huaneng 45.05MW Wind Power Project , China
The Guangdong Nan’ao Huaneng 45.05MW Wind Power Project includes the installation of 53 sets of turbines, each has a capacity of 850KW, providing a total installed capacity of 45.05MW. The manufacturer is Vestas. The Project activity achieved greenhouse gas (GHG) emission reductions by avoiding CO2 emission from the business-as-usual scenario electricity generation of those fossil fuel-fired power plants connected into the South China Grid.
0299/2: Guangdong Nan’ao Huaneng 45.05MW Wind Power Project , China
The Guangdong Nan’ao Huaneng 45.05MW Wind Power Project includes the installation of 53 sets of turbines, each has a capacity of 850KW, providing a total installed capacity of 45.05MW. The manufacturer is Vestas. The Project activity achieved greenhouse gas (GHG) emission reductions by avoiding CO2 emission from the business-as-usual scenario electricity generation of those fossil fuel-fired power plants connected into the South China Grid.
0312/1: 18 MW Kemphole Mini Hydel Scheme (KMHS), by International Power Corporation Limited, India
The project involves the implementation of a run-of-river hydro project on the Kemphole stream. The installed capacity of the plant is 18 MW el. The electricity generated is sold primarily to the state grid.
0312/2: 18 MW Kemphole Mini Hydel Scheme (KMHS), by International Power Corporation Limited, India
The project involves the implementation of a run-of-river hydro project on the Kemphole stream. The installed capacity of the plant is 18 MW el. The electricity generated is sold primarily to the state grid.
0312/3: 18 MW Kemphole Mini Hydel Scheme (KMHS), by International Power Corporation Limited, India
The project involves the implementation of a run-of-river hydro project on the Kemphole stream. The installed capacity of the plant is 18 MW el. The electricity generated is sold primarily to the state grid.
0312/4: 18 MW Kemphole Mini Hydel Scheme (KMHS), by International Power Corporation Limited, India
The project involves the implementation of a run-of-river hydro project on the Kemphole stream. The installed capacity of the plant is 18 MW el. The electricity generated is sold primarily to the state grid.
0327/1: Lohgarh, Chakbhai and Sidhana Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 5.2 MW at Lohgarh (2 MW), Chakbhai (2 MW) and Sidhana (1.2 MW). The electricity generated will be sold primarily to the state grid.
0327/2: Lohgarh, Chakbhai and Sidhana Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 5.2 MW at Lohgarh (2 MW), Chakbhai (2 MW) and Sidhana (1.2 MW). The electricity generated will be sold primarily to the state grid.
0327/3: Lohgarh, Chakbhai and Sidhana Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 5.2 MW at Lohgarh (2 MW), Chakbhai (2 MW) and Sidhana (1.2 MW). The electricity generated will be sold primarily to the state grid.
0328/1: Dolowal, Salar and Bhanubhura Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 4.2 MW at Dolowal, Salar and Bhanabhura. The electricity generated will be sold primarily to the state grid.
0328/2: Dolowal, Salar and Bhanubhura Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 4.2 MW at Dolowal, Salar and Bhanabhura. The electricity generated will be sold primarily to the state grid.
0328/3: Dolowal, Salar and Bhanubhura Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 4.2 MW at Dolowal, Salar and Bhanabhura. The electricity generated will be sold primarily to the state grid.
0329/1: Babanpur, Killa and Sahoke Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 3.75 MW at Babanpur (1 MW), Killa (1.75 MW) and Sahoke (1 MW). The electricity generated will be sold primarily to the state grid.
0329/2: Babanpur, Killa and Sahoke Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 3.75 MW at Babanpur (1 MW), Killa (1.75 MW) and Sahoke (1 MW). The electricity generated will be sold primarily to the state grid.
0329/3: Babanpur, Killa and Sahoke Mini Hydroelectric Projects, India
The project involves the implementation of three mini hydroelectric power plants aggregating to 3.75 MW at Babanpur (1 MW), Killa (1.75 MW) and Sahoke (1 MW). The electricity generated will be sold primarily to the state grid.
0330/1: Manal, Chandni and Timbi Small Hydroelectric Projects of HCPL , India
The purpose of the project is to generate electricity by utilizing the run-of-the river. As per the PDD the project consists of three small hydroelectric projects (SHEP’s) of Himalayan Crest Power Limited (HCPL) aggregating to 9.0 MW in the District of Sirmour, Himachal Pradesh, India
0330/2: Manal, Chandni and Timbi Small Hydroelectric Projects of HCPL , India
The purpose of the project is to generate electricity by utilizing the run-of-the river. As per the PDD the project consists of three small hydroelectric projects (SHEP’s) of Himalayan Crest Power Limited (HCPL) aggregating to 9.0 MW in the District of Sirmour, Himachal Pradesh, India
0330/3: Manal, Chandni and Timbi Small Hydroelectric Projects of HCPL , India
The purpose of the project is to generate electricity by utilizing the run-of-the river. As per the PDD the project consists of three small hydroelectric projects (SHEP’s) of Himalayan Crest Power Limited (HCPL) aggregating to 9.0 MW in the District of Sirmour, Himachal Pradesh, India
0330/4: Manal, Chandni and Timbi Small Hydroelectric Projects of HCPL , India
The purpose of the project is to generate electricity by utilizing the run-of-the river. As per the PDD the project consists of three small hydroelectric projects (SHEP’s) of Himalayan Crest Power Limited (HCPL) aggregating to 9.0 MW in the District of Sirmour, Himachal Pradesh, India
0331/1: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0331/2: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0331/3: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0331/4: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0331/5: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0331/6: Biomass based independent power project at Malwa Power Private Limited, Mukatsar, Punjab, India
The purpose of the project is to utilize biomass available in the region for effective generation of electricity supply to the grid to meet the increasing energy demand in the region. The equipment installed comprises a 7.5 MW bleed cum condensing turbine and a 31.5 tons per hour and 67 atmosphere pressure boiler. The project is located in Punjab state in the village Gulabewalla in the Mukatsar district.
0332/1: Ajbapur Sugar Complex Cogeneration Project, India
Ajbapur Sugar Complex Cogeneration Project, India
0332/2: Ajbapur Sugar Complex Cogeneration Project, India
The purpose of the project is to utilize bagasse available from the sugar manufacturing process for effective generation and supply of electricity to the grid to meet the increasing energy demand in the region.
0332/3: Ajbapur Sugar Complex Cogeneration Project, India
The purpose of the project is to utilize bagasse available from the sugar manufacturing process for effective generation and supply of electricity to the grid to meet the increasing energy demand in the region.
0332/4: Ajbapur Sugar Complex Cogeneration Project, India
The purpose of the project is to utilize bagasse available from the sugar manufacturing process for effective generation and supply of electricity to the grid to meet the increasing energy demand in the region.
0361/1: Optimum utilisation of clinker by PPC production at Binani Cement Limited, Rajasthan , India
The project activity entails a reduction of the clinker content by producing the Portland Pozzolana Cement threby replacing an equivalent amount of clinker at Binani Cement`s cement manufacturing units at Binanigram, Rajasthan. The project activity aims to optimally utilize the clinker in PPC manufacturing. Reduction in percentage of clinker used in cement manufacturing would eventually be helpful in reducing GHGs emissions associated with clinker manufacturing.
0361/2: Optimum utilisation of clinker by PPC production at Binani Cement Limited, Rajasthan , India
The project activity entails a reduction of the clinker content by producing the Portland Pozzolana Cement threby replacing an equivalent amount of clinker at Binani Cement`s cement manufacturing units at Binanigram, Rajasthan. The project activity aims to optimally utilize the clinker in PPC manufacturing. Reduction in percentage of clinker used in cement manufacturing would eventually be helpful in reducing GHGs emissions associated with clinker manufacturing.
0373/1: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/2: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/3: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/4: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/5: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/6: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/7: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/8: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/9: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/10: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/11: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/12: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/13: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/14: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0373/15: São João Landfill Gas to Energy Project (SJ) , Brazil
“São João Landfill Gas to Energy Project (SJ)” is a project designed to explore the landfill gas produced in Sao Joao landfill, one of the landfills in Sao Paulo, Brazil. This landfill is located in the metropolitan region of São Paulo, Brazil’s biggest city and financial center of the country. Aiming to avoid environmental problems related to methane emissions, including also global warming, “São João Landfill Gas to Energy Project (SJ)” was the designed solution created by Biogás.
0376/1: Taraila Small Hydroelectric Project of Ginni Global Ltd., India
The project activity as per the registered PDD involves the run-of-river small hydroelectric project without involving storage of water and the project is located at Taraila Nallah which is a tributary of Birah Nallah in Himachal Pradesh. As per the registered PDD, Project would generate electricity and sell it to the state grid of Himachal Pradesh State Electricity Board (HPSEB). The project activity is a small hydroelectric project and their annual emission reductions as projected in the registered PDD is 25 190 tCO2e per year.
0376/2: Taraila Small Hydroelectric Project of Ginni Global Ltd., India
The project activity as per the registered PDD involves the run-of-river small hydroelectric project without involving storage of water and the project is located at Taraila Nallah which is a tributary of Birah Nallah in Himachal Pradesh. As per the registered PDD, Project would generate electricity and sell it to the state grid of Himachal Pradesh State Electricity Board (HPSEB). The project activity is a small hydroelectric project and their annual emission reductions as projected in the registered PDD is 25 190 tCO2e per year.
0376/3: Taraila Small Hydroelectric Project of Ginni Global Ltd., India
The project activity as per the registered PDD involves the run-of-river small hydroelectric project without involving storage of water and the project is located at Taraila Nallah which is a tributary of Birah Nallah in Himachal Pradesh. As per the registered PDD, Project would generate electricity and sell it to the state grid of Himachal Pradesh State Electricity Board (HPSEB). The project activity is a small hydroelectric project and their annual emission reductions as projected in the registered PDD is 25 190 tCO2e per year.
0393/1: El Gallo Hydroelectric Project, Mexico
The El Gallo Project consists of a 30 MW power plant at the existing dam of El Gallo on the Cutzamala River in the state of Guerrero. The dam was built between 1979 and 1998, with the two-fold objective of (i) irrigation and (ii) clean electricity generation. However, due to lack of funds the electricity generation was not implemented before. The project uses the existing pattern of irrigation flow releases to generate electricity.
0393/2: El Gallo Hydroelectric Project, Mexico
The El Gallo Project consists of a 30 MW power plant at the existing dam of El Gallo on the Cutzamala River in the state of Guerrero. The dam was built between 1979 and 1998, with the two-fold objective of (i) irrigation and (ii) clean electricity generation. However, due to lack of funds the electricity generation was not implemented before. The project uses the existing pattern of irrigation flow releases to generate electricity.
0394/1: Waste heat recovery based captive power project at Monnet , India
The purpose of the waste heat recovery project is to maximise the energy efficiency of the sponge iron manufacturing thereby recovering the high amount of heat escaping in the flue gases and converting it into useful power leading to environmental improvement as well as energy conservation. The project is recovering the sensible heat present in the waste gases coming out from the Direct Reduction Iron (DRI) Kiln for generating power.
0394/2: Waste heat recovery based captive power project at Monnet , India
The purpose of the waste heat recovery project is to maximise the energy efficiency of the sponge iron manufacturing thereby recovering the high amount of heat escaping in the flue gases and converting it into useful power leading to environmental improvement as well as energy conservation. The project is recovering the sensible heat present in the waste gases coming out from the Direct Reduction Iron (DRI) Kiln for generating power.
0425/1: Aguascalientes – EcoMethane Landfill Gas to Energy Project, Mexico
The objective of the Project is to collect and flare the LFG generated at the Cumbres landfill, and to utilize the LFG generated at the San Nicolas landfill. This will involve investing in a highly efficient gas collection system, flaring equipment, and once the project secures a power purchase contract, a modular electricity generation plant. The generators will combust the methane in the LFG to produce electricity for export to the grid. Excess LFG, and all gas collected during periods when electricity is not produced, will be flared.
0425/2: Aguascalientes – EcoMethane Landfill Gas to Energy Project, Mexico
The objective of the Project is to collect and flare the LFG generated at the Cumbres landfill, and to utilize the LFG generated at the San Nicolas landfill. This will involve investing in a highly efficient gas collection system, flaring equipment, and once the project secures a power purchase contract, a modular electricity generation plant. The generators will combust the methane in the LFG to produce electricity for export to the grid. Excess LFG, and all gas collected during periods when electricity is not produced, will be flared.
0425/3: Aguascalientes – EcoMethane Landfill Gas to Energy Project, Mexico
The objective of the Project is to collect and flare the LFG generated at the Cumbres landfill, and to utilize the LFG generated at the San Nicolas landfill. This will involve investing in a highly efficient gas collection system, flaring equipment, and once the project secures a power purchase contract, a modular electricity generation plant. The generators will combust the methane in the LFG to produce electricity for export to the grid. Excess LFG, and all gas collected during periods when electricity is not produced, will be flared.
0432/1: VGL - Waste Heat based 4 MW Captive Power Project at Raipur, India
Vandana Global Limited has implemented a waste heat recovery based power project at its manufacturing facility in Raipur, Chattisgarh, India. The project activity involves utilisation of sensible heat of waste gases from the Direct Reduction Iron (DRI) kiln to produce steam for power generation.
0432/2: VGL - Waste Heat based 4 MW Captive Power Project at Raipur, India
Vandana Global Limited has implemented a waste heat recovery based power project at its manufacturing facility in Raipur, Chattisgarh, India. The project activity involves utilisation of sensible heat of waste gases from the Direct Reduction Iron (DRI) kiln to produce steam for power generation.
0446/1: PetroSA Biogas to Energy Project, South Africa
PetroSA (The Petroleum Oil and Gas Corporation of South Africa) is a state-owned petroleum refinery which is situated some 12 kilometres from Mossel Bay, on the south coast of South Africa. The production process at the plant results in waste process water that has been processed through anaerobic digestion. The anaerobic digestion is continuous and a critical process for the operation of the PetroSA plant. In the anaerobic digestion process biogas is naturally generated.
0450/1: Methane Capture and Combustion from Swine Manure Treatment Project at PT Indotirta Suaka Bulan Farm in Indonesia
The project activity involves the installation of anaerobic digesters to collect and combust the methane from the manure treatment system of the pig farm PT Indotirta Suaka, which is locate in the Bulan Island, Indonesia. Through the implementation of this technology the methane emission reduction will be achieved
0450/2: Methane Capture and Combustion from Swine Manure Treatment Project at PT Indotirta Suaka Bulan Farm in Indonesia
The project activity involves the installation of anaerobic digesters to collect and combust the methane from the manure treatment system of the pig farm PT Indotirta Suaka, which is locate in the Bulan Island, Indonesia. Through the implementation of this technology the methane emission reduction will be achieved
0458/1: Advanced swine manure treatment in Maitenlahue and La Manga, Chile
The project consists of an advanced improvement to the common practice of swine waste treatment in the country, reducing an important volume of greenhouse gases. The technology implementation is based on the use of an activated sludge treatment plant and a storage lagoon from where treated residues are finally employed for irrigation purposes.
0459/1: Pronaca: Afortunados Swine Waste Management, Ecuador
Beginning in August 2000, Pronaca, Ecuador’s leading pork and food production company, initiated a voluntary process to implement advanced waste management systems in order to reduce greenhouse gas emissions and other environmental impacts at a number of their facilities. The current predominant method of manure management for Ecuadorian swine producers is the use of active anaerobic lagoon manure treatment. In the case of the project farm, there is no subsequent use of manure nutrients after anaerobic lagoon treatment.
0459/2: Pronaca: Afortunados Swine Waste Management, Ecuador
Beginning in August 2000, Pronaca, Ecuador’s leading pork and food production company, initiated a voluntary process to implement advanced waste management systems in order to reduce greenhouse gas emissions and other environmental impacts at a number of their facilities. The current predominant method of manure management for Ecuadorian swine producers is the use of active anaerobic lagoon manure treatment. In the case of the project farm, there is no subsequent use of manure nutrients after anaerobic lagoon treatment.
0459/3: Pronaca: Afortunados Swine Waste Management, Ecuador
Beginning in August 2000, Pronaca, Ecuador’s leading pork and food production company, initiated a voluntary process to implement advanced waste management systems in order to reduce greenhouse gas emissions and other environmental impacts at a number of their facilities. The current predominant method of manure management for Ecuadorian swine producers is the use of active anaerobic lagoon manure treatment. In the case of the project farm, there is no subsequent use of manure nutrients after anaerobic lagoon treatment.
0459/4: Pronaca: Afortunados Swine Waste Management, Ecuador
Beginning in August 2000, Pronaca, Ecuador’s leading pork and food production company, initiated a voluntary process to implement advanced waste management systems in order to reduce greenhouse gas emissions and other environmental impacts at a number of their facilities. The current predominant method of manure management for Ecuadorian swine producers is the use of active anaerobic lagoon manure treatment. In the case of the project farm, there is no subsequent use of manure nutrients after anaerobic lagoon treatment.
0460/1: Pronaca: Tropicales-Plata Swine Waste Management
For the purposes of this Project Activity, only manure methane emissions from the baseline and project cases will be considered. Future submissions will consider emissions reductions due to improved nitrogen management systems.
0460/2: Pronaca: Tropicales-Plata Swine Waste Management
For the purposes of this Project Activity, only manure methane emissions from the baseline and project cases will be considered. Future submissions will consider emissions reductions due to improved nitrogen management systems.
0461/1: Pronaca: Valentina-San Javier Swine Waste Management, Ecuador
The project activity involves the implementation of Deep Bedding System in the “Valentina – San Javier” Swine Farm in Ecuador.
0461/2: Pronaca: Valentina-San Javier Swine Waste Management, Ecuador
The project activity involves the implementation of Deep Bedding System in the “Valentina – San Javier” Swine Farm in Ecuador.
0461/3: Pronaca: Valentina-San Javier Swine Waste Management, Ecuador
The project activity involves the implementation of Deep Bedding System in the “Valentina – San Javier” Swine Farm in Ecuador.
0486/5: Horizonte Wind Power Generation Project, Brazil
The project activity consists in generating renewable energy through wind power resource and in selling the generated output to the Brazilian South-Southeast-Midwest (S-SE-CO) grid through a power purchase agreement. The wind power project contributes to the reduction of GHG emissions by replacing the electricity generated in fossil fuelled power plants connected to the grid.
0489/1: Repowering Small Hydro Plants (SHP) in the State of São Paulo, Brazil
The purpose of the project “Repowering Small Hydro Plants (SHP) in the State of São Paulo, Brazil” is the upgrade of CPFL´s SHPs in the State of Sao Paulo, south-eastern Brazil. In this region, all major hydropower potential have long been tapped, together with most of the smaller ones as well. Expanding generation in the region brings the advantage of increasing energy supply in the country´s richest region with lower transmission losses and thus avoiding the more environmentally damaging thermal plants and hydropower plants in the Amazon region.
0492/1: Eecopalsa – biogas recovery and electricity generation from Palm Oil Mill Effluent ponds, Honduras
The proposed bundle consists of two project activities which together form a wastewater treatment system which intents to capture methane directly emitted from the Palm Oil Mill Effluent (POME) ponds and use it for the generation of grid connected renewable electricity.
0492/2: Eecopalsa – biogas recovery and electricity generation from Palm Oil Mill Effluent ponds, Honduras
The proposed bundle consists of two project activities which together form a wastewater treatment system which intents to capture methane directly emitted from the Palm Oil Mill Effluent (POME) ponds and use it for the generation of grid connected renewable electricity.
0492/3: Eecopalsa – biogas recovery and electricity generation from Palm Oil Mill Effluent ponds, Honduras
The proposed bundle consists of two project activities which together form a wastewater treatment system which intents to capture methane directly emitted from the Palm Oil Mill Effluent (POME) ponds and use it for the generation of grid connected renewable electricity.
0493/1: Indocement Alternative Fuels Project, Indonesia
The purpose of this project is to reduce CO2 emissions through use of alternative fuels in clinker burning. Coal, oil, and natural gas are the traditional fuel inputs into the cement production process. The project aims at introducing alternative fuels to substitute the fossil fuels, predominantly coal, that were consumed during clinker burning at Indocement’s production plants.
0493/2: Indocement Alternative Fuels Project, Indonesia
The purpose of this project is to reduce CO2 emissions through use of alternative fuels in clinker burning. Coal, oil, and natural gas are the traditional fuel inputs into the cement production process. The project aims at introducing alternative fuels to substitute the fossil fuels, predominantly coal, that were consumed during clinker burning at Indocement’s production plants.
0508/1: Onyx Alexandria Landfill Gas Capture and Flaring Project, Egypt
The purpose of the project activity is to maximise the capture of landfill gas (LFG) from two new landfill sites and destroying it by flaring. It applies the CDM methodology ACM0001, vers.2.
0508/3: Onyx Alexandria Landfill Gas Capture and Flaring Project, Egypt
The purpose of the project activity is to maximise the capture of landfill gas (LFG) from two new landfill sites and destroying it by flaring. It applies the CDM methodology ACM0001, vers.2.
0526/1: Indocement Blended Cement Project, Indonesia
The aim of this project is to manufacture and sell a new type of cement categorized under a new Cement Standard. In this project, calcination-, fuel-, and power-related CO2 emission reductions are achieved by lowering the clinker content per ton of cement.
0526/2: Indocement Blended Cement Project, Indonesia
The aim of this project is to manufacture and sell a new type of cement categorized under a new Cement Standard. In this project, calcination-, fuel-, and power-related CO2 emission reductions are achieved by lowering the clinker content per ton of cement.
0554/1: Luertai 12.2 MW Hydropower Station Project, Lintan County, Gannan Autonomous Tibetan Prefecture, Gansu province, China
The project activity involves the construction and operation of a run-of-river hydropower station of 12.2MW at the main stream of the Tao River in Lintan County, Gannan Tibetan Autonomous Prefecture of Gansu Province, China, East. The main objective of the project is to generate power from a hydropower station in Gansu Province and contribute to the sustainability of power generation of the North West China Grid.
0556/1: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries and sponge iron kilns for effective generation of electricity. The electricity is primarily consumed in-house at Haldia unit of ECL and surplus is wheeled to the Khardah unit.
0556/2: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries and sponge iron kilns for effective generation of electricity. The electricity is primarily consumed in-house at Haldia unit of ECL and surplus is wheeled to the Khardah unit.
0556/3: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries and sponge iron kilns for effective generation of electricity. The electricity is primarily consumed in-house at Haldia unit of ECL and surplus is wheeled to the Khardah unit.
0556/4: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries and sponge iron kilns for effective generation of electricity. The electricity is primarily consumed in-house at Haldia unit of ECL and surplus is wheeled to the Khardah unit.
0558/1: Jendarata Steam and Powerplant, Malaysia
The project is to replace the existing low efficient biomass fired, fire-tube boilers with a more efficient, water-tube biomass reciprocating grade boiler in the palm oil mill.
0558/2: Jendarata Steam and Powerplant, Malaysia
The project is to replace the existing low efficient biomass fired, fire-tube boilers with a more efficient, water-tube biomass reciprocating grade boiler in the palm oil mill.
0588/1: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries for effective generation of electricity. The electricity is primarily consumed in-house at Rachhagunneri unit of LIL and surplus is exported to the state grid.
0588/2: 12MW Captive Power Project based on Waste Heat Recovery of Industrial Waste Gases, India
The purpose of the project is to utilize sensible heat of the waste gases from non-recovery type coke oven batteries for effective generation of electricity. The electricity is primarily consumed in-house at Rachhagunneri unit of LIL and surplus is exported to the state grid.
0614/2: Perlabi Hydroelectric Project (PHP), Ecuador
The project activity is a run of river hydroelectric plant with a rated capacity of 2.74 MW; the intake is connected to the power house by a 2 190 m pipeline. Two injectors are available to control the water inflow to the turbine, this is directed connected to the generator and the power house is connected to the Ecuadorian national grid.
0614/3: Perlabi Hydroelectric Project (PHP), Ecuador
The project activity is a run of river hydroelectric plant with a rated capacity of 2.74 MW; the intake is connected to the power house by a 2 190 m pipeline. Two injectors are available to control the water inflow to the turbine, this is directed connected to the generator and the power house is connected to the Ecuadorian national grid.
0649/3: Trojes Hydropower project, Mexico
The objective of the proposed project activity is to generate renewable electricity using hydroelectric resources and to sell the generated output to Mexican consumer partners on the basis of power purchase agreements, using the Comisión Federal de Electricidad transmission system to wheel the energy. The project activity generates GHG emission reductions by avoiding electricity generation, and CO2 emissions, at fossil fuel-fired power plants that would be generating otherwise.
0660/1: AWMS Methane Recovery Project MX06-S-44, Sonora, México
The purpose of this project is to mitigate and recover animal effluent related GHG by improving AWMS practices.
0696/1: Usha Martin Limited - Waste Heat Recovery Based Captive Power Project activity, India
Usha Martin Limited has implemented a waste heat recovery based power project at its steel manufacturing facility in Jamshedpur, Jharkhand, India. The project activity involves utilisation of sensible heat of waste gases from the Direct Reduction Iron (DRI) kiln to produce steam for power generation.
0708/1: Huaycoloro landfill gas capture and combustion, Peru
The project’s purpose is to reduce greenhouse gases emissions, in particular reduce methane emissions through combusting Huaycoloro’s landfill gas to generate electricity up to a generation capacity of 5.74 MW2 and flaring the remaining LFG that is not fed into the 5.74 MWelectricity generator; and reduce carbon dioxide emissions through supplying renewable electricity to the SEIN-National Interconnected Electricity System.
0708/2: Huaycoloro landfill gas capture and combustion, Peru
The project’s purpose is to reduce greenhouse gases emissions, in particular reduce methane emissions through combusting Huaycoloro’s landfill gas to generate electricity up to a generation capacity of 5.74 MW2 and flaring the remaining LFG that is not fed into the 5.74 MWelectricity generator; and reduce carbon dioxide emissions through supplying renewable electricity to the SEIN-National Interconnected Electricity System.
0736/1: 7.5 MW Grid Connected Biomass Power Project, India
The project involves the implementation of a biomass-based renewable power generation plant using direct controlled combustion technology. The installed capacity of the plant is 7.5 MW at State Industries Promotion Corporation of Tamil Nadu Industrial (SIPCOT) Complex, Thiruvengaivasal Village, Kulathur Taluka, Pudukkottai District in Tamilnadu and is supplying power to Tamil Nadu State in Electricity Board (TNEB) grid.
0736/2: 7.5 MW Grid Connected Biomass Power Project, India
The project involves the implementation of a biomass-based renewable power generation plant using direct controlled combustion technology. The installed capacity of the plant is 7.5 MW at State Industries Promotion Corporation of Tamil Nadu Industrial (SIPCOT) Complex, Thiruvengaivasal Village, Kulathur Taluka, Pudukkottai District in Tamilnadu and is supplying power to Tamil Nadu State in Electricity Board (TNEB) grid.
0736/3: 7.5 MW Grid Connected Biomass Power Project, India
The project involves the implementation of a biomass-based renewable power generation plant using direct controlled combustion technology. The installed capacity of the plant is 7.5 MW at State Industries Promotion Corporation of Tamil Nadu Industrial (SIPCOT) Complex, Thiruvengaivasal Village, Kulathur Taluka, Pudukkottai District in Tamilnadu and is supplying power to Tamil Nadu State in Electricity Board (TNEB) grid.
0767/1: HFC23 Decomposition Project at Zhonghao Chenguang Research Institute of Chemical Industry, Zigong, SiChuan Province, China
The project activity involves the installation of an plasma arc facility to decompose the HFC23 generated as by-product of Unit A of HCFC22 production units of Zhonghao Chenguang Research Institute of Chemical Industry, Zigong, SiChuan Province, China.
0770/1: Huaibei Haizi and Luling Coal Mine Methane Utilization Project, China
The project activity is located in Haizi and Luling coalmines of Huaibei Mining (Group) Co., Ltd. Through improvement of the drainage system, it is possible to use coalmine methane for power generation and waste heat recovery.
0773/1: Ceran’s Monte Claro Run-of-river Hydropower Plant CDM Project Activity, Brazil
The project consists of a run-of-river hydropower plant with a total installed capacity of 130 MW.
0785/2: Chilatán Hydroelectric Project, Mexico
The objective of the proposed project activity is to generate renewable electricity using hydroelectric resources and to sell the generated output to Mexican consumer partners (primarily industrial users and municipalities) on the basis of power purchase agreements (PPA’s), using the Comisión Federal de Electricidad (CFE) transmission system to wheel the energy.
0791/1: Maguan Daliangzi Hydro Power Project, China
The project activity involves the installation of new hydropower station of 32 MW in the remote Maguan County of Yunnan Province in South Western China.
0791/2: Maguan Daliangzi Hydro Power Project, China
The project activity involves the installation of new hydropower station of 32 MW in the remote Maguan County of Yunnan Province in South Western China.
0791/3: Maguan Daliangzi Hydro Power Project, China
The project activity involves the installation of new hydropower station of 32 MW in the remote Maguan County of Yunnan Province in South Western China.
0799/1: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/2: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/3: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/4: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/5: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/6: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0799/7: Santa Marta Landfill Gas (LFG) Capture Project, Chile
Santa Marta Landfill Gas (LFG) Capture Project is a project designed to explore the landfill gas produced in Santa Marta landfill, one of the landfills in Santiago, Chile. This landfill is located in the metropolitan region of Santiago in the Talagante Province, Chile’s biggest city and financial center of the country.
0802/1: Rice husk based cogeneration power plant-II at SBPML, India
The purpose of the project activity is to have combined heat and power generation to meet energy requirements and to improve overall efficiency of the manufacturing facility. The project involves a biomass-based co-generation power plant which utilizes direct combustion boiler technology.
0802/2: Rice husk based cogeneration power plant-II at SBPML, India
The purpose of the project activity is to have combined heat and power generation to meet energy requirements and to improve overall efficiency of the manufacturing facility. The project involves a biomass-based co-generation power plant which utilizes direct combustion boiler technology.
0803/1: Bagasse based Co-generation Project at Titawi Sugar Complex, India
The proposed project activity envisages installation of one number of 90 Tons per Hour (TPH) nominal capacity high pressure boilers with steam outlet pressure of 86 kg/cm2 and one number of backpressure turbo generator of 20.0 MW capacity.
0804/1: Bagasse based Co-generation Project at Nanglamal Sugar Complex, India
The proposed project activity envisages installation of one number of 120 Tons per Hour (TPH) nominal capacity high pressure boilers with steam outlet pressure of 86 kg/cm2 and one number of backpressure turbo generator of 20.0 MW capacity.
0805/1: Bagasse based Co-generation Project at Mawana Sugar Works, India
The project activity consists of traveling grate boiler of 90 tons per hour (TPH) capacity supplied by Thermax Babcock and Wilcox Limited. Two turbo generators of Siemens make are installed in the project activity.
0807/1: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/2: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/3: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/4: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/5: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/6: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/7: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/8: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/9: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/10: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/11: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/12: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0807/13: Frio Industrias Argentinas S.A (“FIASA”) Hydro-fluorocarbon 23 (“HFC23”) Capture, Storage and Decomposition Project, Argentina
The proposed project aims to reduce GHG emissions by capturing and destroying thermally HFC23 gas produced during the production process of HCFC22 in the production plant of Frío Industrias Argentinas S.A. placed in the province of San Luís, Argentina. The project involves the installation of a thermal oxidation reactor for the decomposition of the fluorocarbons.
0813/1: Installation of cogeneration project at sugar manufacturing unit of Mawana Sugars Limited, Titawi, India
Under present arrangement, heat and power requirement at the Titawi Sugar Complex is being met by low pressure boilers and turbo-generators (TG). There are three boilers and four turbo generators to meet the process steam and electricity requirement of the sugar unit. Bagasse generated by sugar mill is used for operating the existing units.
0822/1: Loma Los Colorados Landfill Gas Project, Chile
“Loma Los Colorados Landfill Gas Project” is a project designed to capture and destroy the me-thane produced in the landfill using an efficient and controlled flaring system. This landfill is lo-cated in the community of Til-Til, 63.5 km north of Santiago, near the village of Montenegro, Chile.
0822/2: Loma Los Colorados Landfill Gas Project, Chile
“Loma Los Colorados Landfill Gas Project” is a project designed to capture and destroy the me-thane produced in the landfill using an efficient and controlled flaring system. This landfill is lo-cated in the community of Til-Til, 63.5 km north of Santiago, near the village of Montenegro, Chile.
0822/3: Loma Los Colorados Landfill Gas Project, Chile
“Loma Los Colorados Landfill Gas Project” is a project designed to capture and destroy the me-thane produced in the landfill using an efficient and controlled flaring system. This landfill is lo-cated in the community of Til-Til, 63.5 km north of Santiago, near the village of Montenegro, Chile.
0828/2: Quimvale and Gas Natural Fuel Switch Project, Brazil
Quimvale is a chemical installation that produces CaCO3 (precipitate). In order to produce CaCO3, a sequence of chemical reactions and a drying out process for the final product are required. The project activity consists of the investment in adapting the previous boiler (used for the drying out process), which utilized fuel oil to one which utilizes natural gas.
0837/2: Kaifeng Jinkai N2O Abatement Project, China
The aim of the project activity is to reduce N2O emissions in the tail gas at nitric acid production process by installation of a DeN2O catalyst at the medium-pressure line.
0839/1: Talia Landfill Gas Recovery Project and Electricity Production, Israel
The purpose of the project is to extract landfill gas from an existing landfill and uses its methane content for energy production. The project is located in the Jordan Valley near the agriculture community Menahamia.
0839/2: Talia Landfill Gas Recovery Project and Electricity Production, Israel
The purpose of the project is to extract landfill gas from an existing landfill and uses its methane content for energy production. The project is located in the Jordan Valley near the agriculture community Menahamia.
0840/1: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0840/2: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0840/3: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0840/4: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0840/5: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0840/6: Pansan Coal Mine Methane Utilisation and Destruction Project, China
The purpose of the project activity is to capture Coal Mine Methane (CMM) and to utilise or destroy it. The Pansan CMM utilisation project consists of two main activities replacing the surface venting of the drained CMM.
0845/1: Zhangbei Mijiagou Windfarm Project, China
Zhangbei Mijiagou 49.5MW windfarm project is located nearby Mijiagou village in the west of Zhangbei county, Hebei province, P.R. China. A decision has been made to install a total of 33 wind turbines, each with a power output of 1 500 kW to best suit the local conditions. The total power capacity, therefore, of the Zhangbei Mijiagou Windfarm project will be 49.5 MW.
0840/2: Zhangbei Mijiagou Windfarm Project, China
Zhangbei Mijiagou 49.5MW windfarm project is located nearby Mijiagou village in the west of Zhangbei county, Hebei province, P.R. China. A decision has been made to install a total of 33 wind turbines, each with a power output of 1 500 kW to best suit the local conditions. The total power capacity, therefore, of the Zhangbei Mijiagou Windfarm project will be 49.5 MW.
0845/3: Zhangbei Mijiagou Windfarm Project, China
Zhangbei Mijiagou 49.5MW windfarm project is located nearby Mijiagou village in the west of Zhangbei county, Hebei province, P.R. China. A decision has been made to install a total of 33 wind turbines, each with a power output of 1 500 kW to best suit the local conditions. The total power capacity, therefore, of the Zhangbei Mijiagou Windfarm project will be 49.5 MW.
0868/5: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/6: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/7: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/8: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/9: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/10: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/11: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/12: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/13: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0868/14: No.2 HFC23 Decomposition Project of Zhejiang Juhua Co., Ltd, P. R. China
The project comprises a decomposition of HFC23 in a HCFC22 production plant. The proposed project involves the installation of a HFC23 collection system including three HFC23 buffer tanks in this project.
0872/1: 4.0 MW Power Plant Using Clinker Cooling Gas Waste Heat, India
Purpose of the project activity is to generate clean energy through Organic Rankine process Cycle (ORC) by using the waste heat generated during the clinker cooler process of cement manufacturing process at UltraTech Cement Limited. The electricity generated from 4MW power plants is utilized for captive purpose.
0908/1: Landfill gas recovery and electricity generation at “Mtoni Dumpsite”, Dar Es Salaam, Tanzania
The purpose of this project is to flare the dump gas captured and use it for electricity generation in “Mtoni Dumpsite, Dar es Salaam, Tanzania. This project will effect a reduction in greenhouse gas emissions through the combustion of methane contained in the biogas extracted from the dump site.
0908/2: Landfill gas recovery and electricity generation at “Mtoni Dumpsite”, Dar Es Salaam, Tanzania
The purpose of this project is to flare the dump gas captured and use it for electricity generation in “Mtoni Dumpsite, Dar es Salaam, Tanzania. This project will effect a reduction in greenhouse gas emissions through the combustion of methane contained in the biogas extracted from the dump site.
0908/3: Landfill gas recovery and electricity generation at “Mtoni Dumpsite”, Dar Es Salaam, Tanzania
The purpose of this project is to flare the dump gas captured and use it for electricity generation in “Mtoni Dumpsite, Dar es Salaam, Tanzania. This project will effect a reduction in greenhouse gas emissions through the combustion of methane contained in the biogas extracted from the dump site.
0911/1: ESTRE Itapevi Landfill Gas Project (EILGP), Brazil
The purpose of the project “ESTRE Itapevi Landfill Gas Project (EILGP)” is focused on the capturing and flaring of landfill gas produced at CGR (Centro de Gerenciamento de Residuos Itapevi). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0911/2: ESTRE Itapevi Landfill Gas Project (EILGP), Brazil
The purpose of the project “ESTRE Itapevi Landfill Gas Project (EILGP)” is focused on the capturing and flaring of landfill gas produced at CGR (Centro de Gerenciamento de Residuos Itapevi). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0911/3: ESTRE Itapevi Landfill Gas Project (EILGP), Brazil
The purpose of the project “ESTRE Itapevi Landfill Gas Project (EILGP)” is focused on the capturing and flaring of landfill gas produced at CGR (Centro de Gerenciamento de Residuos Itapevi). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0911/4: ESTRE Itapevi Landfill Gas Project (EILGP), Brazil
The purpose of the project “ESTRE Itapevi Landfill Gas Project (EILGP)” is focused on the capturing and flaring of landfill gas produced at CGR (Centro de Gerenciamento de Residuos Itapevi). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
0927/1: Landfill Gas utilization at Seelong Sanitary Landfill, Malaysia
The project deals with methane capture, emission reductions, flaring and power production at Seelong Sanitary Landfill in Johor Bahru, Malaysia. Southern Waste Management Sdn. Bhd. (SWM) is the concessionaire of the Seelong Sanitary Landfill, and is also responsible for waste collection in the southern part of peninsula of Malaysia.
0941/1: Sudokwon Landfill Gas Electricity Generation Project (50MW) , Rep. of Korea
As activities of transforming waste gas into resources, Sudokwon Landfill site Management Corporation (from here after SLC) have decided to install Landfill Gas (from here after LFG) power plant after reviewing a plan of medium/high energy content gas production and electric power generation in 2000. LFG collection potential rate is about 75%, generating capacity of this plant was determined as 50MW. This project activity involves this specific type of installation.
0941/2: Sudokwon Landfill Gas Electricity Generation Project (50MW) , Rep. of Korea
As activities of transforming waste gas into resources, Sudokwon Landfill site Management Corporation (from here after SLC) have decided to install Landfill Gas (from here after LFG) power plant after reviewing a plan of medium/high energy content gas production and electric power generation in 2000. LFG collection potential rate is about 75%, generating capacity of this plant was determined as 50MW. This project activity involves this specific type of installation.
0941/3: Sudokwon Landfill Gas Electricity Generation Project (50MW) , Rep. of Korea
As activities of transforming waste gas into resources, Sudokwon Landfill site Management Corporation (from here after SLC) have decided to install Landfill Gas (from here after LFG) power plant after reviewing a plan of medium/high energy content gas production and electric power generation in 2000. LFG collection potential rate is about 75%, generating capacity of this plant was determined as 50MW. This project activity involves this specific type of installation.
0961/1: Sasol Nitrous Oxide Abatement Project, South Africa
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed. Nitrous Oxide (N2O) is an undesired by-product gas from the manufacture of nitric acid. Nitrous oxide is formed during the catalytic oxidation of Ammonia. Over a suitable catalyst, a maximum 98% (typically 92-96%) of the fed Ammonia is converted to Nitric Oxide (NO). The remainder participates in undesirable side reactions that lead to the production of Nitrous Oxide, among other compounds.
0961/2: Sasol Nitrous Oxide Abatement Project, South Africa
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed. Nitrous Oxide (N2O) is an undesired by-product gas from the manufacture of nitric acid. Nitrous oxide is formed during the catalytic oxidation of Ammonia. Over a suitable catalyst, a maximum 98% (typically 92-96%) of the fed Ammonia is converted to Nitric Oxide (NO). The remainder participates in undesirable side reactions that lead to the production of Nitrous Oxide, among other compounds.
0982/1: DSCL Sugar Ajbapur Cogeneration Project Phase II , India
The proposed CDM project activity is the expansion of the cogeneration unit at the DSCL Sugar-Ajbapur plant located in the district of Lakhimpur Kheri in central Uttar Pradesh, India. Two new high pressure (87kg/cm2) and high efficiency boilers, of 60 tonnes per hour (TPH) capacity each, will be installed along with a 20MW extraction-condensing turbine (TG6). The installation of new equipment will allow the factory to export renewable electricity to the Uttar Pradesh electricity grid.
0995/1: Fujian Dongshan Wujiaobay 30MW Wind Power Project , China
The project owned by Dongshan Aozaishan Wind Power Development Co.Ltd. involves the installation of 15 turbines, each of which has a capacity of 2 000 kW (Vestas V80-2000kW of Denmark), providing a total amount of installation capacity of 30 MW. The project is sited within Dongshan Island of Dongshan County, Zhangzhou City in Fujian Province of South-eastern China along the Wujiao bay.
0995/2: Fujian Dongshan Wujiaobay 30MW Wind Power Project , China
The project owned by Dongshan Aozaishan Wind Power Development Co.Ltd. involves the installation of 15 turbines, each of which has a capacity of 2 000 kW (Vestas V80-2000kW of Denmark), providing a total amount of installation capacity of 30 MW. The project is sited within Dongshan Island of Dongshan County, Zhangzhou City in Fujian Province of South-eastern China along the Wujiao bay.
0995/3: Fujian Dongshan Wujiaobay 30MW Wind Power Project , China
The project owned by Dongshan Aozaishan Wind Power Development Co.Ltd. involves the installation of 15 turbines, each of which has a capacity of 2 000 kW (Vestas V80-2000kW of Denmark), providing a total amount of installation capacity of 30 MW. The project is sited within Dongshan Island of Dongshan County, Zhangzhou City in Fujian Province of South-eastern China along the Wujiao bay.
0995/4: Fujian Dongshan Wujiaobay 30MW Wind Power Project , China
The project owned by Dongshan Aozaishan Wind Power Development Co.Ltd. involves the installation of 15 turbines, each of which has a capacity of 2 000 kW (Vestas V80-2000kW of Denmark), providing a total amount of installation capacity of 30 MW. The project is sited within Dongshan Island of Dongshan County, Zhangzhou City in Fujian Province of South-eastern China along the Wujiao bay.
1002/1: Electricity generation by utilization of waste heat from calcined petroleum coke production process, India
The project activity consists of a Waste Heat Recovery Boiler (WHRB) of capacity 115.80 TPH and 65.00 kg/cm2, of ALSTOM make also known as WHRB 2. WHRB 2 in conjunction with a 49.50 MW turbo generator of ABB make constitutes 25 MW installed capacity of waste heat based power generation in the project activity as per the registered PDD. Also as per the PDD the turbo generator draws steam through a common header from another two boilers i.e. WHRB 1 and Circulating Fluidized Bed Boiler (CFBB) of make American Schack Company and Foster Wheeler Pyropower respectively.
1002/2: Electricity generation by utilization of waste heat from calcined petroleum coke production process, India
The project activity consists of a Waste Heat Recovery Boiler (WHRB) of capacity 115.80 TPH and 65.00 kg/cm2, of ALSTOM make also known as WHRB 2. WHRB 2 in conjunction with a 49.50 MW turbo generator of ABB make constitutes 25 MW installed capacity of waste heat based power generation in the project activity as per the registered PDD. Also as per the PDD the turbo generator draws steam through a common header from another two boilers i.e. WHRB 1 and Circulating Fluidized Bed Boiler (CFBB) of make American Schack Company and Foster Wheeler Pyropower respectively.
1003/1: Ramgarh Chini Mills RE project , India
The purpose of the project is the installation of a new power plant next to the existing plant at Ramgarh Chini Mills sugar factory.
1011/1: N2O Emission Reduction in nitric acid plant Paulínia, SP, Brazil
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed. Nitrous Oxide (N2O) is an undesired by-product gas from the manufacture of nitric acid. Nitrous oxide is formed during the catalytic oxidation of Ammonia. Over a suitable catalyst, a maximum 98% (typically 92-96%) of the fed Ammonia is converted to Nitric Oxide (NO). The remainder participates in undesirable side reactions that lead to the production of Nitrous Oxide, among other compounds.
1011/2: N2O Emission Reduction in nitric acid plant Paulínia, SP, Brazil
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed. Nitrous Oxide (N2O) is an undesired by-product gas from the manufacture of nitric acid. Nitrous oxide is formed during the catalytic oxidation of Ammonia. Over a suitable catalyst, a maximum 98% (typically 92-96%) of the fed Ammonia is converted to Nitric Oxide (NO). The remainder participates in undesirable side reactions that lead to the production of Nitrous Oxide, among other compounds.
1011/3: N2O Emission Reduction in nitric acid plant Paulínia, SP, Brazil
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed. Nitrous Oxide (N2O) is an undesired by-product gas from the manufacture of nitric acid. Nitrous oxide is formed during the catalytic oxidation of Ammonia. Over a suitable catalyst, a maximum 98% (typically 92-96%) of the fed Ammonia is converted to Nitric Oxide (NO). The remainder participates in undesirable side reactions that lead to the production of Nitrous Oxide, among other compounds.
1027/1: Transalloys Manganese Alloy Smelter Energy Efficiency Project , South Africa
The Transalloys Manganese Alloy Smelter Energy Efficiency Project, developed by Highveld Steel and Vanadium Corporation, is an industrial energy efficiency project that will reduce the electricity consumption in the production of silicomanganese (SiMn) alloy (a key component in steel making) at its Witbank facility in South Africa. The project involves a retrofit of current furnaces with new design of electric arc furnaces, electrode assemblies and new control and peripheral systems.
1036/1: Khon Kaen Sugar Power Plant , Thailand
The proposed CDM project activity is biomass based power generation project for exporting the power to Thai grid. The project activity is the biomass generated in house and purchased from outside is fed into the boiler which produces steam and the steam produced is fed to the turbo generator to produce electricity. The electricity generated is consumed in house as well as sold to the grid.
1038/1: 6.5MW WHR Project in Huasheng Tianya Cement Co., Ltd. , China
The project owned by Huasheng Tianya Cement Co., Ltd. utilizes the low temperature waste heat of the exit gases from Suspension Preheater (SP) and Air Quenching Chamber (AQC) from a 5000t/d clinker production line. The project entity has built one 6,5 MW captive power station. This includes the installation of 2 WHR boilers (one for SP and one for AQC), one steam turbine and one generator.
1038/2: 6.5MW WHR Project in Huasheng Tianya Cement Co., Ltd. , China
The project owned by Huasheng Tianya Cement Co., Ltd. utilizes the low temperature waste heat of the exit gases from Suspension Preheater (SP) and Air Quenching Chamber (AQC) from a 5000t/d clinker production line. The project entity has built one 6,5 MW captive power station. This includes the installation of 2 WHR boilers (one for SP and one for AQC), one steam turbine and one generator.
1040/1: Korat Waste To Energy, Thailand
The project activity involves the installation of a treat the wastewater form the starch industry, at the Sanguan Wongse Industries (SWI) facility in Korat Thailand. The Anaerobic Baffled Reactor removes the organic material in the wastewater, thus reducing the Chemical Oxygen Demand (COD) and subsequent fugitive CH4 emissions. Biogas produced is being used in the SWI facility to create heat to dry the wet tapioca starch cake to the final dry starch product, displacing over 9.8 million liters of fuel oil per year currently employed to dry the starch product.
1040/2: Korat Waste To Energy, Thailand
The project activity involves the installation of a treat the wastewater form the starch industry, at the Sanguan Wongse Industries (SWI) facility in Korat Thailand. The Anaerobic Baffled Reactor removes the organic material in the wastewater, thus reducing the Chemical Oxygen Demand (COD) and subsequent fugitive CH4 emissions. Biogas produced is being used in the SWI facility to create heat to dry the wet tapioca starch cake to the final dry starch product, displacing over 9.8 million liters of fuel oil per year currently employed to dry the starch product.
1075/1: Guangzhou Xingfeng Landfill Gas Recovery and Electricity Generation CDM Project , China
The proposed project will generate electricity by collecting and using xingfeng landfill gas, connecting to local power grid, which will not only guarantee the landfill site safety and utilize the waste resource with environmental benefit, but also avoid landfill gas emission to the atmosphere directly and reduce coal consumption for generation in local grid, therefore, the GHG emissions are reduced and the climate change is mitigated.
1079/1: Gansu Diebu Duoer 32MW Hydropower Project, China
The project is a new reservoir type hydropower plant with the average power density of 74 W/m2. The proposed installed capacity is 32 MW consisting of three 10 MW and one 2 MW turbines. The predicted power generation is 138 363MWh per year. The project is located 300m downriver to the intersection of Duoer River and Axia River on a branch of Bailong River in Diebu County, Gansu Province, People’s Republic of China.
1079/2: Gansu Diebu Duoer 32MW Hydropower Project, China
The project is a new reservoir type hydropower plant with the average power density of 74 W/m2. The proposed installed capacity is 32 MW consisting of three 10 MW and one 2 MW turbines. The predicted power generation is 138 363MWh per year. The project is located 300m downriver to the intersection of Duoer River and Axia River on a branch of Bailong River in Diebu County, Gansu Province, People’s Republic of China.
1120/1: Jiaozishan Landfill Gas Recovery and Utilisation Project , China
The project activity aims to set up a collection and heating system using landfill gas collected from the Jiaozishan landfill. The project will supply hot water to hotels, bathhouses and other haet consumers in Najing city, thereby avoiding methane emissions from disposal at a landfill where methane emissions are causedba anaerobic processes.
1133/1: Terrestre Ambiental Landfill Gás Project , Brazil
The objective of the “Terrestre Ambiental Landfill Gas Project” is to capture and flare the landfill gas generated at the CGR Piaçaguera landfill in order to avoid emissions of methane to the atmosphere. The landfill is located in the city of Santos, São Paulo State, Brazil. The CGR Piaçaguera landfill has the capacity to receive 3 million tons of waste.
1133/2: Terrestre Ambiental Landfill Gás Project , Brazil
The objective of the “Terrestre Ambiental Landfill Gas Project” is to capture and flare the landfill gas generated at the CGR Piaçaguera landfill in order to avoid emissions of methane to the atmosphere. The landfill is located in the city of Santos, São Paulo State, Brazil. The CGR Piaçaguera landfill has the capacity to receive 3 million tons of waste.
1134/1: ESTRE Pedreira Landfill Gás Project (EPLGP) , Brazil
The purpose of the project “ESTRE Pedreira Landfill Gás Project (EPLGP)” is focused on the capturing and flaring of landfill gas produced at CDR Pedreira (Centro de Disposição de resíduos Ltda.). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
1134/2: ESTRE Pedreira Landfill Gás Project (EPLGP) , Brazil
The purpose of the project “ESTRE Pedreira Landfill Gás Project (EPLGP)” is focused on the capturing and flaring of landfill gas produced at CDR Pedreira (Centro de Disposição de resíduos Ltda.). Through flaring of the landfill gas by an active recovery system, methane emissions released to the atmosphere are avoided. The project substitutes the previous installed passive venting system, thus increasing the efficiency in gas collection and flaring.
1135/1: Jiangxi Fengcheng Mining Administration CMM Utilization Project , China
15*500kW CMM gensets started operation in Qujiang coalmine from April 2007. CMM utilized by the project is drained from Jianxin, Pinghu and Qujiang mines of Fengcheng Mining Administration. The emissions reductions are achieved by methane (CH4) capture and destruction, CMM power generation substituting the fossil fuel power generation.
1135/2: Jiangxi Fengcheng Mining Administration CMM Utilization Project , China
15*500kW CMM gensets started operation in Qujiang coalmine from April 2007. CMM utilized by the project is drained from Jianxin, Pinghu and Qujiang mines of Fengcheng Mining Administration. The emissions reductions are achieved by methane (CH4) capture and destruction, CMM power generation substituting the fossil fuel power generation.
1135/3: Jiangxi Fengcheng Mining Administration CMM Utilization Project , China
15*500kW CMM gensets started operation in Qujiang coalmine from April 2007. CMM utilized by the project is drained from Jianxin, Pinghu and Qujiang mines of Fengcheng Mining Administration. The emissions reductions are achieved by methane (CH4) capture and destruction, CMM power generation substituting the fossil fuel power generation.
1135/4: Jiangxi Fengcheng Mining Administration CMM Utilization Project , China
15*500kW CMM gensets started operation in Qujiang coalmine from April 2007. CMM utilized by the project is drained from Jianxin, Pinghu and Qujiang mines of Fengcheng Mining Administration. The emissions reductions are achieved by methane (CH4) capture and destruction, CMM power generation substituting the fossil fuel power generation.
1136/1: Gansu Zhouqu Shimenping 15 MW Hydropower Station Project , China
The Gansu Zhouqu Shimenping 15MW Hydropower Station Project will involve the construction of a run-of-river hydropower station at the main stream of Bailongjiang River in Zhouqu County, Gannan Tibetan Autonomous Prefectureof Gansu Province.
1136/2: Gansu Zhouqu Shimenping 15 MW Hydropower Station Project , China
The Gansu Zhouqu Shimenping 15MW Hydropower Station Project will involve the construction of a run-of-river hydropower station at the main stream of Bailongjiang River in Zhouqu County, Gannan Tibetan Autonomous Prefectureof Gansu Province.
1139/1: Bagasse based Cogeneration Project at Pudukkottai Tamil Nadu, India
The proposed CDM project activity is bagasse based power generation project for captive use in sugar manufacturing unit; located at Pudukkottai, Tamil Nadu state in India.
1150/1: La Ventosa Wind Energy Project, Mexico
The La Ventosa Project consists of the construction and operation of a 102 MW wind farm in Mexico’s southern state of Oaxaca, in the municipalities of Juchitan de Zaragoza and Asunción Ixtlaltepec, in the vicinity of the La Ventosa town. The main objective of the Project is to generate electricity from wind, thus increasing the percentage of renewable sourced power in Mexico’s electricity grid, and, at the same time, contributing to the environmental, social and economic sustainability of the region.
1153/1: Methane recovery and utilisation project at United Plantations Berhad, Jendarata Palm Oil Mill, Malaysia
The project activity involves the installation of a closed continuous-flow stirred tank reactor (CSTR) anaerobic digester plant for the treatment of palm oil mill effluent at United Plantations (UP) Bhd Palm Oil Mill at Jendarata Estate, Teluk Intan. The CSTR system is equipped with a dual-function complete mixing mechanism, comprising pump-aided circulation and gas-lifting mixing, to facilitate long-term continuous operations without any interruptions for sludge removal. The biogas generated will be captured in the enclosed anaerobic digester tanks.
1153/2: Methane recovery and utilisation project at United Plantations Berhad, Jendarata Palm Oil Mill, Malaysia
The project activity involves the installation of a closed continuous-flow stirred tank reactor (CSTR) anaerobic digester plant for the treatment of palm oil mill effluent at United Plantations (UP) Bhd Palm Oil Mill at Jendarata Estate, Teluk Intan. The CSTR system is equipped with a dual-function complete mixing mechanism, comprising pump-aided circulation and gas-lifting mixing, to facilitate long-term continuous operations without any interruptions for sludge removal. The biogas generated will be captured in the enclosed anaerobic digester tanks.
1172/1: Fujian Nanridao 16.15MW Wind Power Project , China
Fujian Nanridao 16.15MW Wind Power Project (hereafter referred as the proposed project) is a grid connected renewable energy project. The objective of the proposed project is to generate electricity from wind resources using advanced wind power generation technology and deliver to the East China Power Grid.
1177/1: Fujian Pingtan Changjiang’ao 100 MW Wind Power Project , China
Fujian Pingtan Changjiang’ao Wind Power Project (hereafter referred as the proposed project) is a grid connected renewable energy project. The objective of the proposed project is to generate electricity from wind resources using advanced wind power generation technology and deliver to the East China Power Grid. The implementation of the proposed project will achieve CO2 emission reduction by replacing electricity generated by fossil fuel fired power plant.
1186/1: Biomass thermal energy plant – Hartalega Sdn.Bhd, Malaysia
Hartalega produces high quality rubber gloves for the food industry and medical applications. The production process requires a large amount of energy under the form of hot water (cleaning & rinsing of moulds) and hot air (drying process of coagulant and latex). These two heat media are produced by conventional boilers fired by fossil fuel. The project activity consists of replacing the conventional boilers (8 units) by three biomass boilers and to increase the heat generation capacity by installing an additional biomass boiler (phase 2: boiler no 4).
1223/1: Wahei Hydroelectric Project, China
The purpose of the Project is to utilize the hydrological resource of the Wahei River in a diversion type hydro power scheme to generate zero carbon emission electricity for the Central China Power Grid. The project will generate Certified Emission Reductions (CERs) by displacing electricity generation from grid connected fossil fuel-fired power plants that would otherwise be generating the electricity needed.
1228/1: Waste Gas based Captive Power Plant in Liangang Group, China
The Project clearly fits into the development priority of China. It will support China in stimulating and accelerating the technology development and the commercialization of integrated resource utilization technologies and energy saving. It will therefore help reduce greenhouse gas (GHG) emissions resulting from the high-growth, coal-dominated business-as-usual scenario.
1228/2: Waste Gas based Captive Power Plant in Liangang Group, China
The Project clearly fits into the development priority of China. It will support China in stimulating and accelerating the technology development and the commercialization of integrated resource utilization technologies and energy saving. It will therefore help reduce greenhouse gas (GHG) emissions resulting from the high-growth, coal-dominated business-as-usual scenario.
1229/1: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/2: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/3: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/4: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/5: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/6: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/7: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/8: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/9: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/10: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/11: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1229/12: Catalytic N2O destruction project in the tail gas of the nitric acid plant PANNA 3 of Enaex S.A. , Chile
The project consists of the installation of a tertiary N2O reduction technology (EnviNOx® process) in the tail gas stream of the nitric acid production plant of ENAEX S.A., Chile. Nitrous oxide which is formed as by-product of the nitric acid production will be removed by the EnviNOx®-System which applies a special catalyst developed for this specific purpose. The emission reductions are a result of the catalytic reduction of nitrous oxide in the implemented EnviNOx® System.
1243/1: Xiaoshuichi Hydro Power Project of Lanzhou City, Gansu Province, P.R. China
The purpose of the Gansu Xiaoshuichi Hydropower Project (hereinafter “GXHP project”) is to generate electricity by building a new run-of-river hydropower plant, without any reservoirs. The power plant would use part of the water channel along the Datonghe River that was built in 1995, known as the “Yin Da Ru Qin” hydraulic project.
1249/1: Palmas del Espino – Biogas recovery and heat generation from Palm Oil Mill Effluent (POME) ponds, Peru
Palmas del Espino – Biogas recovery and heat generation from Palm Oil Mill Effluent (POME) ponds, Peru” involves the recovery of biogas and the generation of heat. The biogas is produced from the palm oil mill effluent (POME) ponds at Palmas del Espino’s palm oil mill located in Peru.
1249/2: Palmas del Espino – Biogas recovery and heat generation from Palm Oil Mill Effluent (POME) ponds, Peru
Palmas del Espino – Biogas recovery and heat generation from Palm Oil Mill Effluent (POME) ponds, Peru” involves the recovery of biogas and the generation of heat. The biogas is produced from the palm oil mill effluent (POME) ponds at Palmas del Espino’s palm oil mill located in Peru.
1258/1: Quezon City Controlled Disposal Facility Biogas Emission Reduction Project , Philippines
The Project activity involves the extraction, collection, processing and flaring, including the conversion into electricity of the biogas emissions at the Quezon City Controlled Disposal Facility (“Facility”) located in Area 2, Barangay Payatas, Quezon City, the Philippines.
1258/2: Quezon City Controlled Disposal Facility Biogas Emission Reduction Project , Philippines
The Project activity involves the extraction, collection, processing and flaring, including the conversion into electricity of the biogas emissions at the Quezon City Controlled Disposal Facility (“Facility”) located in Area 2, Barangay Payatas, Quezon City, the Philippines.
1258/3: Quezon City Controlled Disposal Facility Biogas Emission Reduction Project , Philippines
The Project activity involves the extraction, collection, processing and flaring, including the conversion into electricity of the biogas emissions at the Quezon City Controlled Disposal Facility (“Facility”) located in Area 2, Barangay Payatas, Quezon City, the Philippines.
1258/5: Quezon City Controlled Disposal Facility Biogas Emission Reduction Project , Philippines
The Project activity involves the extraction, collection, processing and flaring, including the conversion into electricity of the biogas emissions at the Quezon City Controlled Disposal Facility (“Facility”) located in Area 2, Barangay Payatas, Quezon City, the Philippines.
1338/1: Lufeng Jiadong First Phase Wind Farm Project, China
The Lufeng Jiadong First Phase Wind Farm Project (hereafter referred to as the Project) is sited on the east coast of the Jiadong County, Lufeng City, Guangdong Province, P.R.China. The objective of the Project is to utilize the wind power for generating electricity which will be sold into the China Southern Power Grid. The total installed capacity of the Project is 30.6 MW with 36 sets of turbines with a unit capacity of 850 kW. The estimated electricity delivered to the China Southern Power Grid by the Project is 48.874 GWh per year via a 110 kV outlet circuit.
1338/2: Lufeng Jiadong First Phase Wind Farm Project, China
The Lufeng Jiadong First Phase Wind Farm Project (hereafter referred to as the Project) is sited on the east coast of the Jiadong County, Lufeng City, Guangdong Province, P.R.China. The objective of the Project is to utilize the wind power for generating electricity which will be sold into the China Southern Power Grid. The total installed capacity of the Project is 30.6 MW with 36 sets of turbines with a unit capacity of 850 kW. The estimated electricity delivered to the China Southern Power Grid by the Project is 48.874 GWh per year via a 110 kV outlet circuit.
1343/1: Xiaoshan Power Plant’s NG Power Generation Project of Zhejiang Southeast Electric Power Co., Ltd. , China
Xiaoshan Power Plant’s NG Power Generation Project of Zhejiang Southeast Electric Power Co., Ltd. (hereafter called “the project”) is the construction and operation of a new natural gas fired grid-connected power plant owned by ZheJiang Southeast Electric Power Co., Ltd. The project will install two sets of gas-steam combined cycle for power generation units with the total rated output of 2×403MW.
1343/2: Xiaoshan Power Plant’s NG Power Generation Project of Zhejiang Southeast Electric Power Co., Ltd. , China
Xiaoshan Power Plant’s NG Power Generation Project of Zhejiang Southeast Electric Power Co., Ltd. (hereafter called “the project”) is the construction and operation of a new natural gas fired grid-connected power plant owned by ZheJiang Southeast Electric Power Co., Ltd. The project will install two sets of gas-steam combined cycle for power generation units with the total rated output of 2×403MW.
1397/1: Comprehensive utilization of waste coal gas for electricity generation project in Shaanxi Xinglong Cogeneration Co. Ltd , China
The proposed projects includes two 130t/h gas-fired boilers and two sets of 25MW condensing steam turbine with bleeding. The fuel to be used in the proposed project will be the waste gas from blast furnace and converter which is surplus coal gas after balance and now open flaring in absence of the proposed project. The project participants intends to utilize these waste gases from Shaanxi Longmen Iron & Steel for power generation.
1424/1: Carhuaquero IV Hydroelectric Power Plant, Peru
The proposed project is a run-of-river hydropower plant, located 80 kilometers (km) east of Chiclayo City, in the Department of Cajamarca, north of Lima at 372 meters (m) above sea level (masl). The plant will have an installed capacity of 9.7 MW and a projected yearly average generation of 42 Gigawatt hours (GWh). The purpose of Carhuaquero IV Power Plant (the Project) is renewable electricity generation to be supplied to the Peruvian National Inter-connected Electric Grid (SEIN).
1431/1: Sichuan Zhaojiashan 20MW Hydropower Project, China
The Sichuan Zhaojiashan 20MW Hydropower Project(hereafter, the Project) – a run-of-river type hydro power plant—is developed by Sichuan Hongchang Electric Power Co., Ltd., a county-level private company. The purpose of the Project is to utilize the hydrologic resources of the Yajiageng River to generate zero GHG emission electricity for the Central China Grid.
1435/1: Regional landfill projects in Chile
The project aims at designing, building and operating a highly efficient landfill gas (LFG) collection and flaring system to burn the landfill gas collected on each of the selected sites.
1438/1: Hubei Hefeng Yanzi Town Baishun Village Taohuashan Hydropower Station , China
The proposed project activity involves the construction and operation of a run-of-river diversion type hydropower station; the “Hubei Hefeng Yanzi Town Baishun Village Taohuashan Hydropower Station project”, hereafter referred to as “project” or “proposed project”. The proposed project is located in Baishun Village of Yanzi Town in Hefeng County of Enshi Tujia-Miao Autonomous Prefecture, Hubei Province, China. The dam site located at the Jiufengqiao River and the power plant is located on the side of Nandu River.
1438/2: Hubei Hefeng Yanzi Town Baishun Village Taohuashan Hydropower Station , China
The proposed project activity involves the construction and operation of a run-of-river diversion type hydropower station; the “Hubei Hefeng Yanzi Town Baishun Village Taohuashan Hydropower Station project”, hereafter referred to as “project” or “proposed project”. The proposed project is located in Baishun Village of Yanzi Town in Hefeng County of Enshi Tujia-Miao Autonomous Prefecture, Hubei Province, China. The dam site located at the Jiufengqiao River and the power plant is located on the side of Nandu River.
1450/1: 8MW pure low temperature waste heat recovery (WHR) for power generation in SDIC Hainan Cement Co., Ltd. , China
The Project activity involves the recovery and utilization of waste heat to generate electricity at the SDIC Hainan Cement Co., Ltd in Hainan Province, People’s Republic of China. SDIC Hainan Cement Co., Ltd is equipped with two dry clinker production lines. (one 2,000 t/d new-type dry clinker production line and one 2,500 t/d new-type dry clinker production line) Waste heat generated by the clinker production lines would be discharged via kiln front clinker coolers and kiln rear pre-heaters in the absence of the Project activity.
1450/2: 8MW pure low temperature waste heat recovery (WHR) for power generation in SDIC Hainan Cement Co., Ltd. , China
The Project activity involves the recovery and utilization of waste heat to generate electricity at the SDIC Hainan Cement Co., Ltd in Hainan Province, People’s Republic of China. SDIC Hainan Cement Co., Ltd is equipped with two dry clinker production lines. (one 2,000 t/d new-type dry clinker production line and one 2,500 t/d new-type dry clinker production line) Waste heat generated by the clinker production lines would be discharged via kiln front clinker coolers and kiln rear pre-heaters in the absence of the Project activity.
1453/1: Petrotemex Energy Integration Project, Mexico
The project involves the installation of several equipments to reduce the overheated steam generation in boilers of Cosoleacaque PTA production plant ( switching from the existing turbocompressors, to a new high efficency turbo compressor, new systems generating low-pressure steam using the waste heat, new condensers in dehydration columns, switching from binary distillation to azeotropic distillation) to achieve a more efficient use of energy in the production process of Cosoleacaque plant, in state of Veracruz, in the east of Mexico.
1453/2: Petrotemex Energy Integration Project, Mexico
The project involves the installation of several equipments to reduce the overheated steam generation in boilers of Cosoleacaque PTA production plant ( switching from the existing turbocompressors, to a new high efficency turbo compressor, new systems generating low-pressure steam using the waste heat, new condensers in dehydration columns, switching from binary distillation to azeotropic distillation) to achieve a more efficient use of energy in the production process of Cosoleacaque plant, in state of Veracruz, in the east of Mexico.
1451/1: Emek Hefer Biogas Project, Israel
The project activity involves the installation of a combined heat and power (CHP) plant at an existing biogas reactor at Emek Hefer Kibuzim in Israel which handles manure in 3 phases (pre-treatment, anaerobic digester, effluent and sludge treatment). The biogas reactor was commissioned in December 2005. Presently about 600 t per day of cow manure is delivered to the biogas reactor which generates 880 Nm3/h of biogas with a CH4 content of around 64%.
1483/1: Energeticos Jaremar – Biogas recovery from Palm Oil Mill Effluent (POME) ponds, and heat & electricity generation, Honduras
The proposed project activity involves the covering of two open anaerobic lagoons for the treatment of palm oil mill effluent (POME) at Agrotor’s palm oil mill located in Honduras. The recovered biogas will be utilised on site for the production of heat and electricity.
1488/1: Inner Mongolia Sunjiaying 50.25MW Wind Power Project , China
Inner Mongolia Sunjiaying 50.25MW Wind Power Project (hereafter referred as the proposed project) is a grid connected renewable energy project located in Inner Mongolia Autonomous Region, Northeast China. The objective of the proposed project is to generate electricity using state-of-the-art wind power generation technology and to sell into the State Power Grid. The proposed project will achieve CO2 emission reduction by replacing electricity generated by fossil fuel fired power plant connected into China Northeast Power Grid.
1495/1: Enhancing energy efficiency by replacing batch smelter by continuous smelter at Karaikal, Pondicherry, India
The purpose of the project is to replace the high carbon intensive specific fuel consumption batch smelting process to less specific fuel consumption and energy efficient continuous smelting process for frit production at H & R Johnson (India) limited, Karaikal plant. The project activity involved installation of two continuous smelters with the capacity of 15 tonnes per day & 27 tonnes per day.
1498/1: Baji River Stage I 10MW Run-of-river Hydropower Project, China
Baji River Stage I 10MW Run-of-river Hydropower Project is located in Yanyuan County, Liangshan Yi Autonomous Prefecture, Sichuan Province, People’s Republic of China. It is a run-of-river project with the power density of 22.49W/m2 and the first stage of the Baji River hydropower project as a whole. The proposed project will ease up the tension of local power supply.
1501/1: Liaoning Huanren Niumaodashan Wind Power Project, China
Liaoning Huanren Niumaodashan Wind Power Project is a grid connected renewable energy project, which uses wind power to generate electricity and supplies to the Northeast China Power Grid.
1501/2: Liaoning Huanren Niumaodashan Wind Power Project, China
Liaoning Huanren Niumaodashan Wind Power Project is a grid connected renewable energy project, which uses wind power to generate electricity and supplies to the Northeast China Power Grid.
1501/3: Liaoning Huanren Niumaodashan Wind Power Project, China
Liaoning Huanren Niumaodashan Wind Power Project is a grid connected renewable energy project, which uses wind power to generate electricity and supplies to the Northeast China Power Grid.
1501/4: Liaoning Huanren Niumaodashan Wind Power Project, China
Liaoning Huanren Niumaodashan Wind Power Project is a grid connected renewable energy project, which uses wind power to generate electricity and supplies to the Northeast China Power Grid.
1522/1: Bapan 12.7MW Hydropower Project, China
Bapan Hydropower Project is located in Bapan town, Jiangkou county, Guizhou province, China. The Project is a diversion run-of-river hydropower station.
1533/1: Daguan Linguanyan Small Hydropower Project in Yunnan Province, P. R. China
Daguan Linguanyan Small Hydropower Project in Yunnan Province (DLSHP), P.R.China, is a run-ofriver hydropower project located on Daguan River, Yunnan Province, P.R.China.
1536/1: Guangdong Longtan 2*7MW Hydropower project, China
The Guangdong Longtan 2*7MW Hydropower Project is a run-of-river hydropower project located in Longchuan County, Guangdong Province of the People’s Republic of China. The purpose of the project activity is to generate renewable energy using clean hydropower technology and sell the output electricity into the grid.
1536/2: Guangdong Longtan 2*7MW Hydropower project, China
The Guangdong Longtan 2*7MW Hydropower Project is a run-of-river hydropower project located in Longchuan County, Guangdong Province of the People’s Republic of China. The purpose of the project activity is to generate renewable energy using clean hydropower technology and sell the output electricity into the grid.
1536/3: Guangdong Longtan 2*7MW Hydropower project, China
The Guangdong Longtan 2*7MW Hydropower Project is a run-of-river hydropower project located in Longchuan County, Guangdong Province of the People’s Republic of China. The purpose of the project activity is to generate renewable energy using clean hydropower technology and sell the output electricity into the grid.
1555/1: China Zhijiang Peace Small Hydropower Project, China
Zhijiang Peace Hydropower Project involves the construction and operation of a 13.5MW run-ofriver diversion type hydropower plant. The project will reduce emission of greenhouse gases (GHGs) by partly avoiding operation of existing thermal power plant and future expansion of fossil fuel-based generation by CCPG.
1555/2: China Zhijiang Peace Small Hydropower Project, China
Zhijiang Peace Hydropower Project involves the construction and operation of a 13.5MW run-ofriver diversion type hydropower plant. The project will reduce emission of greenhouse gases (GHGs) by partly avoiding operation of existing thermal power plant and future expansion of fossil fuel-based generation by CCPG.
1555/3: China Zhijiang Peace Small Hydropower Project, China
Zhijiang Peace Hydropower Project involves the construction and operation of a 13.5MW run-ofriver diversion type hydropower plant. The project will reduce emission of greenhouse gases (GHGs) by partly avoiding operation of existing thermal power plant and future expansion of fossil fuel-based generation by CCPG.
1575/1: Kadamane Mini Hydel Scheme-1 (KMHS-1), India
Paschim Hydro Energy Private Limited (PHEPL) has set up a 2 x 4.5 MW Small Hydro Power Project plant in Maranhalli Village, Sakaleshpura Taluk, Hassan district, Karnataka. The objective of the power plant is to utilize the natural water and head available at the project site for generation of clean renewable energy.
1592/1: Huadian Ningxia Ningdong Yangjiayao 45MW Wind-farm Project, China
Huadian Ningxia Ningdong Yangjiayao 45MW Wind-farm Project is a new built wind-farm project, located in the Yangjiayao Village, Majiatan Town, Lingwu City, Ningxia Hui Autonomous Region, P. R. China. The purpose of the project is to generate electricity by using clean wind resources to alleviate electricity shortage in Northwest China.
1592/2: Huadian Ningxia Ningdong Yangjiayao 45MW Wind-farm Project, China
Huadian Ningxia Ningdong Yangjiayao 45MW Wind-farm Project is a new built wind-farm project, located in the Yangjiayao Village, Majiatan Town, Lingwu City, Ningxia Hui Autonomous Region, P. R. China. The purpose of the project is to generate electricity by using clean wind resources to alleviate electricity shortage in Northwest China.
1603/1: Zhengzhou Coal Industry (Group) Co., Ltd. Coalmine Methane Utilization Project , China
Zhengzhou Coal Industry (Group) Co., Ltd. (ZCG) is a state-owned industry group located in Henan Province, Central China. Its current coal production is about 11 million tons of coal a year and is forecast to increase to about 14 million tons within the next 5 years. During its mining activities, methane gas is released and needs to be discharged in order to comply with Chinese mining safety regulations. About 45% of gas is released in the form of coalmine methane (CMM), which is drained directly from ZCG’s coal seams.
1605/1: Shaba 24MW Hydropower Project in Yunnan Province, China
The proposed project is a water-diversion-type run-of-river hydropower plant, a new reservoir without regulation was built, the project activity involves the installation of 3 turbines, each of which has a rated output of 8MW, total capacity is 24MW, the water diversion project includes a 346.5m diversion canal and a 1,825m diversion tunnel. The canal is supported by concrete structure with its cross section to be 4.2*5.0m. The tunnel is in the shape of an arch of 4.2m wide, 5.612m high and 0.4m-0.6m thick. The head pond has two rooms of 6000m3.
1605/2: Shaba 24MW Hydropower Project in Yunnan Province, China
The proposed project is a water-diversion-type run-of-river hydropower plant, a new reservoir without regulation was built, the project activity involves the installation of 3 turbines, each of which has a rated output of 8MW, total capacity is 24MW, the water diversion project includes a 346.5m diversion canal and a 1,825m diversion tunnel. The canal is supported by concrete structure with its cross section to be 4.2*5.0m. The tunnel is in the shape of an arch of 4.2m wide, 5.612m high and 0.4m-0.6m thick. The head pond has two rooms of 6000m3.
1605/3: Shaba 24MW Hydropower Project in Yunnan Province, China
The proposed project is a water-diversion-type run-of-river hydropower plant, a new reservoir without regulation was built, the project activity involves the installation of 3 turbines, each of which has a rated output of 8MW, total capacity is 24MW, the water diversion project includes a 346.5m diversion canal and a 1,825m diversion tunnel. The canal is supported by concrete structure with its cross section to be 4.2*5.0m. The tunnel is in the shape of an arch of 4.2m wide, 5.612m high and 0.4m-0.6m thick. The head pond has two rooms of 6000m3.
1613/1: Yima Coal Industry (Group) Co., Ltd. CMM utilization project , China
Yima Coal Industry Group (YCIG) is a state-owned industry group located in the western part of Henan Province, about 160 km from the capital Zhengzhou. Its annual coal production is expected to reach about 20 million tons by the end of 2007. During its mining activities, methane gas is released from the coal seam and needs to be discharged in order to comply with Chinese mining safety regulations. About 40% of gas is released in the form of coalmine methane (CMM), which is drained directly from YCIG’s coal seams.
1685/1: Zhang Jiagang waste heat recovery from sulphuric acid production for electricity generation project , China
The project activity is developed by TWO LIONS (ZHANGJIAGANG) FINE CHEMICALS CO., LTD (hereafter referred to TFC for short) which will recover waste heat from sulphuric acid production process to produce electricity, displacing part of electricity supplied by the East China Grid which predominantly relies on fossil fuel-fired power plants for power generation.
1685/2: Zhang Jiagang waste heat recovery from sulphuric acid production for electricity generation project , China
The project activity is developed by TWO LIONS (ZHANGJIAGANG) FINE CHEMICALS CO., LTD (hereafter referred to TFC for short) which will recover waste heat from sulphuric acid production process to produce electricity, displacing part of electricity supplied by the East China Grid which predominantly relies on fossil fuel-fired power plants for power generation.
1685/3: Zhang Jiagang waste heat recovery from sulphuric acid production for electricity generation project , China
The project activity is developed by TWO LIONS (ZHANGJIAGANG) FINE CHEMICALS CO., LTD (hereafter referred to TFC for short) which will recover waste heat from sulphuric acid production process to produce electricity, displacing part of electricity supplied by the East China Grid which predominantly relies on fossil fuel-fired power plants for power generation.
1686/1: Waste Heat based Captive Power Project in Hunan Hualing Liangang , China
Hunan Hualing Lianyuan Iron and Steel Co., Ltd. (hereafter referred to as Hunan Hualing Liangang) intends to install a set of 150 t/h Coke Dry Quenching (CDQ) system. The objective of the Waste Heat based Captive Power Project in Hunan Hualing Liangang (hereafter referred to as the Project) is to utilize the CDQ system to recover waste heat of hot red coke to generate electricity, displacing part of the electricity purchased by Hunan Hualing Liangang from the Central China Grid.
1766/1: Shimen Suojie Small Hydropower Project in Changde, P.R. China
The purpose of the project is to generate electricity by using water resources to alleviate electricity shortage in Central China. The project will contribute to the reduction of GHG emission by displacing part of the electricity from the fossil fuel fired power plants of the CCPG, and the expected annual GHG emission reductions over the first crediting period is 40,737 tCO2e/yr, which will contribute to alleviate the climate change.
1766/2: Shimen Suojie Small Hydropower Project in Changde, P.R. China
The purpose of the project is to generate electricity by using water resources to alleviate electricity shortage in Central China. The project will contribute to the reduction of GHG emission by displacing part of the electricity from the fossil fuel fired power plants of the CCPG, and the expected annual GHG emission reductions over the first crediting period is 40,737 tCO2e/yr, which will contribute to alleviate the climate change.
1766/3: Shimen Suojie Small Hydropower Project in Changde, P.R. China
The purpose of the project is to generate electricity by using water resources to alleviate electricity shortage in Central China. The project will contribute to the reduction of GHG emission by displacing part of the electricity from the fossil fuel fired power plants of the CCPG, and the expected annual GHG emission reductions over the first crediting period is 40,737 tCO2e/yr, which will contribute to alleviate the climate change.
1774/1: Electricity generation from mustard crop residues: Tonk, India
The following proposed CDM project activity is located in the State of Rajasthan, India. The project involves the implementation of a biomass-based power generation plant using direct combustion boiler technology by Kalpataru Power Transmission Ltd. (KPTL), a leading firm in the implementation of power transmission and distribution systems. The installed capacity of the plant is 8 MWel. The fuel used is primarily mustard crop residue, which is abundantly available in the vicinity of the site. The electricity generated will be sold primarily to the state grid.
1784/1: Fosfertil Piaçaguera NAP 2 Nitrous Oxide Abatement Project , Brazil
The project activity involves the installation of a secondary catalyst to abate N2O inside the reactor once it is formed.
1784/2: Fosfertil Piaçaguera NAP 2 Nitrous Oxide Abatement Project , Brazil
The project activity involves the installation of a secondary catalyst to abate N2O inside the reactor once it is formed.
1785/1: Guizhou Zhenyuan Putian Hydropower Station, China
The specific project activity, namely Guizhou Zhenyuan Putian Hydropower Station, involves the construction and operation of a mixed type hydropower station, which is located in Putian Village, Qingxi Town, Zhenyuan County, Guizhou Southeast Miao-Dong Autonomous Prefecture, Guizhou Province, People’s Republic of China. The project is developed by Guizhou Zhenyuan Putian Hydropower Co., Ltd. The proposed project will use two turbines with a total installed capacity of 6.4MW.
1785/2: Guizhou Zhenyuan Putian Hydropower Station, China
The specific project activity, namely Guizhou Zhenyuan Putian Hydropower Station, involves the construction and operation of a mixed type hydropower station, which is located in Putian Village, Qingxi Town, Zhenyuan County, Guizhou Southeast Miao-Dong Autonomous Prefecture, Guizhou Province, People’s Republic of China. The project is developed by Guizhou Zhenyuan Putian Hydropower Co., Ltd. The proposed project will use two turbines with a total installed capacity of 6.4MW.
1805/1: Liyujiang Small Hydroelectric Project (LSHP), Hunan Province, China
Liyujiang small hydroelectric project, Hunan Province, China is a newly built hydropower plant. The purpose of the project is to generate electricity by using renewable water resources to alleviate electricity shortage in Central China.
1813/1: China Tumuxi Small Hydropower Project
China Tumuxi Small Hydropower Project (hereinafter referred to as “the project’), a run-of-the-river small hydropower project, is located in Sancha Town, Yongding District, Zhangjiajie city, Hunan province, People's Republic of China. The project includes two cascades hydropower plants. Water of Tumuxi River will be conducted by a tunnel and through the first cascade plant to generate electricity. Then the tail water infuses into Chenjiaxi rivulet, and is conducted by another tunnel to pass through the secondary cascade plant, at last, the water will inflood into Li River.
1813/2: China Tumuxi Small Hydropower Project
China Tumuxi Small Hydropower Project (hereinafter referred to as “the project’), a run-of-the-river small hydropower project, is located in Sancha Town, Yongding District, Zhangjiajie city, Hunan province, People's Republic of China. The project includes two cascades hydropower plants. Water of Tumuxi River will be conducted by a tunnel and through the first cascade plant to generate electricity. Then the tail water infuses into Chenjiaxi rivulet, and is conducted by another tunnel to pass through the secondary cascade plant, at last, the water will inflood into Li River.
1817/1: Fengguang 24.9MW Hydropower Project in Guangdong Province, China
Fengguang 24.9MW Hydropower Project in Guangdong Province, China (hereafter referred to as “the proposed project”) is a run-of-river hydropower project with a total installed capacity of 24.9MW (3×8.3MW). It is located on the Dongjiang River Heyuan City. Dongjiang Fengguang Likou Power Plant Development Co.Ltd is in charge of its construction and operation. The proposed project started its main construction engineering in May 2006, and it is estimated that all the three generators will generate electricity in July 2008.
1817/2: Fengguang 24.9MW Hydropower Project in Guangdong Province, China
Fengguang 24.9MW Hydropower Project in Guangdong Province, China (hereafter referred to as “the proposed project”) is a run-of-river hydropower project with a total installed capacity of 24.9MW (3×8.3MW). It is located on the Dongjiang River Heyuan City. Dongjiang Fengguang Likou Power Plant Development Co.Ltd is in charge of its construction and operation. The proposed project started its main construction engineering in May 2006, and it is estimated that all the three generators will generate electricity in July 2008.
1855/1: CECIC Zhangbei Dayangzhuang Wind Farm Project , China
CECIC Zhangbei Dayangzhuang Wind Farm Project (hereinafter referred to as the proposed project) is located in Zhangbei County, Hebei Province, and is developed by CECIC Wind Power (Zhangbei) Yunwei Co. Ltd. Based on the condition of the project site, the proposed project is planned to install and operate 66 wind turbines of 750kW. Therefore, the total installed capacity of proposed wind farm is 49.5MW.
1887/1: Huainan Panyi and Xieqiao Coal Mine Methane Utilization Project
Huainan Panyi and Xieqiao Coal Mine Methane Utilization Project is located in Huainan City, Anhui Province, P.R.China. The objective of the Project is to utilize the gas which was vented into the atmosphere for energy supply.
1896/1: Jincheng Sihe Coal Mine CMM Generation Project , China
Jincheng Sihe Coal Mine CMM Generation Project (this project) is located within the Sihe Coal Mine, Jiafeng Town, Qinshui County, Jincheng City, Shanxi Province of China. It will utilize the coal mine methane (CMM) currently being vented to the atmosphere for grid-connected power generation with an installed capacity of 120 MW.
1902/1: Fuel Switching at Atocongo Cement Plant and Natural Gas Pipeline Extension, Cementos Lima, Peru
The proposed project “Fuel Switching at Atocongo Cement Plant and Natural Gas Pipeline Extension” consists in the switching from coal to natural gas in two cements kilns at Atocongo Cement Plant, in Peru. The project considers the installation of natural gas burners in the cement kilns and also contemplates the construction of a natural gas pipeline, from a distribution point located 3.5 km south-west from the Atocongo Cement Plant, and the implementation of a regulation and measurement station at the site in order to get the required supply of natural gas.
1902/2: Fuel Switching at Atocongo Cement Plant and Natural Gas Pipeline Extension, Cementos Lima, Peru
The proposed project “Fuel Switching at Atocongo Cement Plant and Natural Gas Pipeline Extension” consists in the switching from coal to natural gas in two cements kilns at Atocongo Cement Plant, in Peru. The project considers the installation of natural gas burners in the cement kilns and also contemplates the construction of a natural gas pipeline, from a distribution point located 3.5 km south-west from the Atocongo Cement Plant, and the implementation of a regulation and measurement station at the site in order to get the required supply of natural gas.
1926/1: Fuxin CMM/CBM Utilization Project in Liaoning Province , China
Fuxin Coal Mine Methane (CMM)/Coal Bed Methane (CBM) Utilization Project (hereafter referred to as “the project”) will use and destroy CMM and CBM that would otherwise have been vented, in new power production facilities and for gas supply to residential consumers. Prior to implementation of the project, the Fuxin mining area makes use of both CMM drainage and mine ventilation to maintain safe methane concentrations within the mines. Of the methane drained prior to the start of the project activity, approximately 85% was vented to the atmosphere.
1926/2: Fuxin CMM/CBM Utilization Project in Liaoning Province , China
Fuxin Coal Mine Methane (CMM)/Coal Bed Methane (CBM) Utilization Project (hereafter referred to as “the project”) will use and destroy CMM and CBM that would otherwise have been vented, in new power production facilities and for gas supply to residential consumers. Prior to implementation of the project, the Fuxin mining area makes use of both CMM drainage and mine ventilation to maintain safe methane concentrations within the mines. Of the methane drained prior to the start of the project activity, approximately 85% was vented to the atmosphere.
2170/1: CECIC HKC Danjinghe Wind Farm Project
The objective of the CECIC HKC Danjinghe Wind Farm Project is to generate renewable electricity using wind power resources and to sell the generated output to the North China Power Grid (NCPG) on the basis of a power purchase agreement (PPA).
2232/1: Catalytic N2O Abatement Project in the tail gas of the Caprolactam production plant in Thailand
The aim of the project activity is to reduce N2O emissions by installation of DeN2O Unit before the Stack, which is called Tertiary Catalyst System or Tail Gas System.
2243/1: Reduction of N2O emissions at shop#25, production line #1 at “Navoiazot” plant, Uzbekistan
Purpose of the project activity and the measures taken to reduce greenhouse gas emissions “Navoiazot” is a chemical fertilizer company of Uzbekistan and its shop#25 is a production plant of nitric acid. From the plant, Nitrous Oxide (N2O), which is an undesired by-product of the nitric acid production process, is released into the atmosphere.
2243/2: Reduction of N2O emissions at shop#25, production line #1 at “Navoiazot” plant, Uzbekistan
Purpose of the project activity and the measures taken to reduce greenhouse gas emissions “Navoiazot” is a chemical fertilizer company of Uzbekistan and its shop#25 is a production plant of nitric acid. From the plant, Nitrous Oxide (N2O), which is an undesired by-product of the nitric acid production process, is released into the atmosphere.
2257/1: Fosfertil Cubatão NAP4 Nitrous Oxide Abatement Project
The project activity involves the installation of a secondary catalyst to abate N2O inside the ammonia burner once it is formed.
2278/1: Xiamen Dongfu Landfill Gas-to-Energy Project
The project activity is to capture and destroy landfill gas (LFG) and produce electricity by installing power generators and flaring system during the fixed 10-year crediting period. The generated electricity by utilizing LFG will be exported for the displacement of the electricity generated by fossil fuel-fired plants connected to the East China Power Grid (ECPG).
2309/1: Shaanxi Xinghua N2O Abatement Project, China
Purpose of the project activity and the measures taken to reduce greenhouse gas emissions Shaanxi Xinghua Chemistry Co., Ltd. mainly manufactures ammonium nitrate and has two nitric acid plants (Line-1 and Line-2). The aim of the project activity is to reduce N2O emissions by installation of secondary catalysts inside the ammonia oxidation reactors (AORs) at both plants of Xinghua.
2314/1: Heilongjiang Chemical N2O Abatement Project, China
The sole purpose of the project is to reduce the current levels of N2O emissions at Heilongjiang Chemical’s nitric acid production plant.
2810/1: Hefei Longquanshan Landfill Gas Power Generation Project
The Project captures the land fill gas that would have been released to the atmosphere without the project activity and generates electricity with the landfill gas. The electricity is supplied to East China Power Grid (ECPG) to replace the electricity generated from fossil-fired power plant of ECPG. The excess captured landfill gas is flared.
2810/2: Hefei Longquanshan Landfill Gas Power Generation Project
The Project captures the land fill gas that would have been released to the atmosphere without the project activity and generates electricity with the landfill gas. The electricity is supplied to East China Power Grid (ECPG) to replace the electricity generated from fossil-fired power plant of ECPG. The excess captured landfill gas is flared.
2959/1: Chengkou County Huangan River Lijiaba Hydroelectric Project
The Project utilises the hydrological resources of the Huangan River in a run of river hydro power facility that generates low emissions electricity for the Central China Power Grid (hereafter referred to as “CCPG”). And the low emissions electricity replaces the higher one generated by the CCPG, reduction of emissions of greenhouse gases (GHG) is produced by the project.
3180/1: Malan Coal Mine Methane Utilisation Project
The purpose of the project activity is the utilization and abatement of coal mine methane (CMM) captured in underground coal mine workings to allow safe coal mining, energy conservation and GHGs emissions reduction at Malan coal mine.
3440/1: Point of Use Abatement Device to Reduce SF6 emissions in LCD Manufacturing Operations in the Republic of Korea (South Korea)
LG Display (LGD) currently uses SF6 in its LCD manufacturing process in Plant 2/3, Plant 4/5, Plant 6 in Gumi, South Korea and Plant 7 in Paju, South Korea. To destroy much of the SF6 vented from the dry etching process, LG International (LGI) and LGD installed an abatement device at the stack of the dry etching chambers in Plant 6.
3440/2: Point of Use Abatement Device to Reduce SF6 emissions in LCD Manufacturing Operations in the Republic of Korea (South Korea)
LG Display (LGD) currently uses SF6 in its LCD manufacturing process in Plant 2/3, Plant 4/5, Plant 6 in Gumi, South Korea and Plant 7 in Paju, South Korea. To destroy much of the SF6 vented from the dry etching process, LG International (LGI) and LGD installed an abatement device at the stack of the dry etching chambers in Plant 6.
3965/1:Anhui Suzhou 2×12.5MW Biomass Power Generation Project
The straw-fired power generation project in Suzhou City, Anhui Province is a biomass residue collection and utilization project invested and operated by Huadian Suzhou
Biomass Power Industrial Co., Ltd.
1543/1: Hot air generation using renewable biomass fuel for spray drying and vertical drying application at H&R Johnson (India) Limited, Dewas, Madhya Pradesh, India
The project activity consists of hot air generation for spray drying operation of the manufacturing process. The Fluidized Bed Combustion (FBC) system which is the heart of hot air generation project comprises of biomass conveying system (bucket elevator), a combustion unit (fuel hopper, Combustion fans, fuel feeder, combustion chamber) and hot gas handling & separation and cleaning section (settling chamber, cyclone, rotary valves, gas duct line, control panel etc). Biomass is fed to the combustion zone with additional air to maintain fluidization of biomass.