Difference between revisions of "Biogas Stoves"
***** (***** | *****) (Created page with " = Introduction = Biogas production depends on the availability of sufficient biomass feedstock, water and space for the digester. Biogas is produced by the anaerobic digesti...") |
***** (***** | *****) m |
||
| Line 4: | Line 4: | ||
Biogas production depends on the availability of sufficient biomass feedstock, water and space for the digester. Biogas is produced by the anaerobic digestion of organic matter under anaerobic conditions. Biogas is comprised primarily of methane and carbon dioxide. At household level, biogas systems can be used to produce fertilizer and for providing energy for cooking and lighting. | Biogas production depends on the availability of sufficient biomass feedstock, water and space for the digester. Biogas is produced by the anaerobic digestion of organic matter under anaerobic conditions. Biogas is comprised primarily of methane and carbon dioxide. At household level, biogas systems can be used to produce fertilizer and for providing energy for cooking and lighting. | ||
| − | This article focusses on biogas cook stoves. For more information on the production of biogas for domestic cooking use please read this article [[ | + | This article focusses on biogas cook stoves. For more information on the production of biogas for domestic cooking use please read this article [[Cooking with Biogas|Cooking with Biogas]]. |
| − | |||
| + | <br/> | ||
= Stove Technology = | = Stove Technology = | ||
| − | Cookstoves and ovens for biogas application are similar to those of conventional appliances running on commercial gas-fuels. A biogas stove usually has a single or double burner with varying gas consumption rates, which is influenced by the pressure provided by the biogas plant and the diameter of the inlet pipe. The burner itself has several parts. The amount of gas that flows into the burner is controlled by the jet, a hole which is carefully sized and defines the power output of the burner. Compared to other gases, biogas needs less air for combustion. Therefore, conventional gas appliances need larger gas jets when they are used for biogas combustion.<ref name="Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014), | + | Cookstoves and ovens for biogas application are similar to those of conventional appliances running on commercial gas-fuels. A biogas stove usually has a single or double burner with varying gas consumption rates, which is influenced by the pressure provided by the biogas plant and the diameter of the inlet pipe. The burner itself has several parts. The amount of gas that flows into the burner is controlled by the jet, a hole which is carefully sized and defines the power output of the burner. Compared to other gases, biogas needs less air for combustion. Therefore, conventional gas appliances need larger gas jets when they are used for biogas combustion.<ref name="Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014), http://dx.doi.org/10.1016/j.biombioe.2014.02.017">Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014),fckLRfckLRhttp://dx.doi.org/10.1016/j.biombioe.2014.02.017</ref> Most of these conventional appliances can be adapted for the use with biogas by the modification of the burners to ensure proper combustion and efficient use of energy. Stoves running on biogas contain a valve to premix the biogas with the right amount of oxygen, a burner to combust the mixture and a structure to hold a pot. Piping is needed to transport the biogas from the digester to the point of use in the cook stove. |
| − | + | More information on biogas burners can also be found in this energypedia article: [[Biogas Appliances|biogas appliances]]. [LF1] | |
| − | + | <br/> | |
<br/> | <br/> | ||
| − | + | = Efficiency of Biogas Stoves = | |
| − | |||
| − | Efficiency of Biogas Stoves | ||
For achieving a high efficiency of biogas stoves, the important factors to be considered in designing a biogas stove are:<ref name="Center for Energy Studies, Institute of Engineering, Tribhuvan University, Pulchowok, Lalitpur (2004): A Final Report On Efficiency Measurement of Biogas Stoves.">Center for Energy Studies, Institute of Engineering, Tribhuvan University, Pulchowok, Lalitpur (2004): A Final Report On Efficiency Measurement of Biogas Stoves.</ref> | For achieving a high efficiency of biogas stoves, the important factors to be considered in designing a biogas stove are:<ref name="Center for Energy Studies, Institute of Engineering, Tribhuvan University, Pulchowok, Lalitpur (2004): A Final Report On Efficiency Measurement of Biogas Stoves.">Center for Energy Studies, Institute of Engineering, Tribhuvan University, Pulchowok, Lalitpur (2004): A Final Report On Efficiency Measurement of Biogas Stoves.</ref> | ||
| − | Burner types (orientations of holes, shape and size of holes, burner size) | + | *Burner types (orientations of holes, shape and size of holes, burner size) |
| + | *Space between burner and the tripod or other vessel supporting mechanism | ||
| + | *air control mechanism and optimization on burning | ||
Furthermore, gas composition, gas pressure, flame speed (velocity), and pot to burner distance are of relevance. A test report of SNV mentions also more general criteria for biogas stove efficiency. This [http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c Popular Summary of the Test Reports on Biogas Stoves and Lamps] presents the test results of biogas stoves of eight countries (Bangladesh, Cambodia, Ethiopia, India, Lesotho, Nepal, Rwanda and Vietnam) carried out in 2007. Most stoves did not meet the general standards for biogas stoves as defined in China and India. On the basis of thermal efficiency alone, the stoves from Bangladesh and Cambodia met the prescribed minimum efficiency of 55% under both the Chinese and the Indian standards. The stove from Rwanda was very close to the prescribed efficiency.<ref name="SNV (2009): Popular Summary of the Test Reports on Biogas Stoves and Lamps prepared by testing institutes in China, India and the Netherlands. http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c">SNV (2009): Popular Summary of the Test Reports on Biogas Stoves and Lamps prepared by testing institutes in China, India and the Netherlands. http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c</ref> | Furthermore, gas composition, gas pressure, flame speed (velocity), and pot to burner distance are of relevance. A test report of SNV mentions also more general criteria for biogas stove efficiency. This [http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c Popular Summary of the Test Reports on Biogas Stoves and Lamps] presents the test results of biogas stoves of eight countries (Bangladesh, Cambodia, Ethiopia, India, Lesotho, Nepal, Rwanda and Vietnam) carried out in 2007. Most stoves did not meet the general standards for biogas stoves as defined in China and India. On the basis of thermal efficiency alone, the stoves from Bangladesh and Cambodia met the prescribed minimum efficiency of 55% under both the Chinese and the Indian standards. The stove from Rwanda was very close to the prescribed efficiency.<ref name="SNV (2009): Popular Summary of the Test Reports on Biogas Stoves and Lamps prepared by testing institutes in China, India and the Netherlands. http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c">SNV (2009): Popular Summary of the Test Reports on Biogas Stoves and Lamps prepared by testing institutes in China, India and the Netherlands. http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c</ref> | ||
| − | < | + | A Water-Boiling-Test of eight different biogas stoves carried out by the Center for Research in Energy and Energy Conservation at the Makerere University in Kampala, Uganda resulted in a much lower efficiency. Many of the locally available gas burners that were tested were of poor quality: they had an overall efficiency of 20% on average and their designs did not follow gas burner theory adequately.<ref name="Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014), http://dx.doi.org/10.1016/j.biombioe.2014.02.017">Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014),fckLRfckLRhttp://dx.doi.org/10.1016/j.biombioe.2014.02.017</ref> Furthermore, the test results showed high levels of carbon monoxide emissions for most of the stoves. |
| − | + | However, lab test results can be very different from using stoves under real life conditions. Unfortunately, field operations and respective efficiency analyses (e.g. through kitchen performance tests) are rarely described and available. | |
| − | + | Consumption of Biogas for Cooking | |
| − | + | Household burners consume approximately 200-450 liters of biogas per hour. The gas consumption for cooking per person lies between 300 and 900 liter per day, the gas consumption per 5-member family for 2 cooked meals between 1500 and 2400 liter per day. With 1 kg cattle dung in warm tropical countries approximately 40 liters of biogas can be produced.<ref name="GTZ/ISAT (1999): Biogas Digest Vol II. Biogas - Application and Product Development. https://energypedia.info/index.php?title=File:Biogas_gate_volume_2.pdf&page=1">GTZ/ISAT (1999): Biogas Digest Vol II. Biogas - Application and Product Development. https://energypedia.info/index.php?title=File:Biogas_gate_volume_2.pdf&page=1</ref> | |
| − | |||
<br/> | <br/> | ||
| − | |||
| − | |||
| − | |||
| + | <br/> | ||
| + | = Further Information = | ||
= References = | = References = | ||
| − | |||
| − | |||
<references /> | <references /> | ||
Revision as of 09:41, 19 December 2016
Introduction
Biogas production depends on the availability of sufficient biomass feedstock, water and space for the digester. Biogas is produced by the anaerobic digestion of organic matter under anaerobic conditions. Biogas is comprised primarily of methane and carbon dioxide. At household level, biogas systems can be used to produce fertilizer and for providing energy for cooking and lighting.
This article focusses on biogas cook stoves. For more information on the production of biogas for domestic cooking use please read this article Cooking with Biogas.
Stove Technology
Cookstoves and ovens for biogas application are similar to those of conventional appliances running on commercial gas-fuels. A biogas stove usually has a single or double burner with varying gas consumption rates, which is influenced by the pressure provided by the biogas plant and the diameter of the inlet pipe. The burner itself has several parts. The amount of gas that flows into the burner is controlled by the jet, a hole which is carefully sized and defines the power output of the burner. Compared to other gases, biogas needs less air for combustion. Therefore, conventional gas appliances need larger gas jets when they are used for biogas combustion.[1] Most of these conventional appliances can be adapted for the use with biogas by the modification of the burners to ensure proper combustion and efficient use of energy. Stoves running on biogas contain a valve to premix the biogas with the right amount of oxygen, a burner to combust the mixture and a structure to hold a pot. Piping is needed to transport the biogas from the digester to the point of use in the cook stove.
More information on biogas burners can also be found in this energypedia article: biogas appliances. [LF1]
Efficiency of Biogas Stoves
For achieving a high efficiency of biogas stoves, the important factors to be considered in designing a biogas stove are:[2]
- Burner types (orientations of holes, shape and size of holes, burner size)
- Space between burner and the tripod or other vessel supporting mechanism
- air control mechanism and optimization on burning
Furthermore, gas composition, gas pressure, flame speed (velocity), and pot to burner distance are of relevance. A test report of SNV mentions also more general criteria for biogas stove efficiency. This Popular Summary of the Test Reports on Biogas Stoves and Lamps presents the test results of biogas stoves of eight countries (Bangladesh, Cambodia, Ethiopia, India, Lesotho, Nepal, Rwanda and Vietnam) carried out in 2007. Most stoves did not meet the general standards for biogas stoves as defined in China and India. On the basis of thermal efficiency alone, the stoves from Bangladesh and Cambodia met the prescribed minimum efficiency of 55% under both the Chinese and the Indian standards. The stove from Rwanda was very close to the prescribed efficiency.[3]
A Water-Boiling-Test of eight different biogas stoves carried out by the Center for Research in Energy and Energy Conservation at the Makerere University in Kampala, Uganda resulted in a much lower efficiency. Many of the locally available gas burners that were tested were of poor quality: they had an overall efficiency of 20% on average and their designs did not follow gas burner theory adequately.[1] Furthermore, the test results showed high levels of carbon monoxide emissions for most of the stoves.
However, lab test results can be very different from using stoves under real life conditions. Unfortunately, field operations and respective efficiency analyses (e.g. through kitchen performance tests) are rarely described and available.
Consumption of Biogas for Cooking
Household burners consume approximately 200-450 liters of biogas per hour. The gas consumption for cooking per person lies between 300 and 900 liter per day, the gas consumption per 5-member family for 2 cooked meals between 1500 and 2400 liter per day. With 1 kg cattle dung in warm tropical countries approximately 40 liters of biogas can be produced.[4]
Further Information
References
- ↑ 1.0 1.1 Tumwesige V, et al., Biogas appliances in Sub-Sahara Africa, Biomass and Bioenergy (2014),fckLRfckLRhttp://dx.doi.org/10.1016/j.biombioe.2014.02.017
- ↑ Center for Energy Studies, Institute of Engineering, Tribhuvan University, Pulchowok, Lalitpur (2004): A Final Report On Efficiency Measurement of Biogas Stoves.
- ↑ SNV (2009): Popular Summary of the Test Reports on Biogas Stoves and Lamps prepared by testing institutes in China, India and the Netherlands. http://m.snvworld.org/en/publications/test-reports-on-biogas-stoves-and-lamps-prepared-by-testing-institutes-in-china-india#.VlQ7FF54m9c
- ↑ GTZ/ISAT (1999): Biogas Digest Vol II. Biogas - Application and Product Development. https://energypedia.info/index.php?title=File:Biogas_gate_volume_2.pdf&page=1
