Biogas production from a systems analytical perspective
(2006)- Abstract
- Anaerobic digestion and the production of biogas can provide an efficient means of meeting several objectives concerning energy, environmental and waste management policy. Interest in biogas is increasing, and new facilities are being built. There is a wide range of potential raw material, and both the biogas and digestates produced can be used in many different applications. The variation in raw materials and digestion processes contributes to the flexibility of biogas production systems, but at the same time makes their analysis and comparison more complicated.
In this thesis, the energy performance in the life cycle of biogas production is assessed, as well as the environmental impact of introducing biogas systems to... (More) - Anaerobic digestion and the production of biogas can provide an efficient means of meeting several objectives concerning energy, environmental and waste management policy. Interest in biogas is increasing, and new facilities are being built. There is a wide range of potential raw material, and both the biogas and digestates produced can be used in many different applications. The variation in raw materials and digestion processes contributes to the flexibility of biogas production systems, but at the same time makes their analysis and comparison more complicated.
In this thesis, the energy performance in the life cycle of biogas production is assessed, as well as the environmental impact of introducing biogas systems to replace various fuels and existing strategies for the handling of various raw materials. The energy performance and environmental impact vary greatly between the biogas systems studied depending on the raw material digested and the reference system replaced. The results are largely dependent on the methodological assumptions made, for example, concerning focus, system boundaries, and how the energy required in joint operations is allocated to the raw materials digested. Many of the environmental implications depend on how changes resulting from non-energy-related aspects of the implementation of biogas production can be taken into account. For example, changes in emission of methane and ammonia from the handling of the raw material or changes in nitrogen leaching from arable land.
There are several potential barriers to the successful implementation of biogas production. The aspect to which most attention was devoted here was the prospect of using digestate from large-scale biogas plants as a fertilizer in agriculture. Reliable and generally accepted disposal of the comparatively large amounts of digestate produced is necessary if biogas production is to be implemented. Agriculture is currently the most common, and sometimes the only suitable means of disposal of the digestate. Serious resistance to or problems associated with this use could therefore jeopardise the development of biogas systems. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/546409
- author
- Berglund, Maria LU
- supervisor
- opponent
-
- Professor Tillman, Anne-Marie, Environmental Systems Analysis, Chalmers Universtiy of Technology
- organization
- publishing date
- 2006
- type
- Thesis
- publication status
- published
- subject
- keywords
- Energiforskning, Energy research, indirect environmental impact, fuel-cycle emissions, environmental systems analysis, energy systems analysis, energy balance, digestate, Anaerobic digestion, biogas
- pages
- 164 pages
- publisher
- Environmental and Energy Systems Studies, Lund university
- defense location
- Room F, Department of Physics, Sölvegatan 14, Lund Institute of Technology
- defense date
- 2006-03-31 09:15:00
- external identifiers
-
- other:ISRN:LUTFD2/TFEM--06/1027--SE+(1--164)
- ISBN
- 91-88360-80-6
- language
- English
- LU publication?
- yes
- additional info
- Maria Berglund and Pål Börjesson. 2006. Assessment of energy performance in the life-cycle of biogas production Biomass & Bioenergy, vol 30 pp 254-266. Environmental and Energy Systems Studies LTH Department of Technology and Society Faculty of Engineering at Lund UniversityPål Börjesson and Maria Berglund. . Environmental systems analysis of biogas systems Part I: Fuel-cycle emissions Biomass & Bioenergy, Environmental and Energy Systems Studies LTH Department of Technology and Society Faculty of Engineering at Lund University (inpress)Pål Börjesson and Maria Berglund. . Environmental systems analysis of biogas systems Part II: The environmental impact of replacing various reference systems Biomass & Bioenergy, (submitted)Maria Berglund. . Prospects for the spreading of digestates from biogas plants on arable land Resources, Conservation and Recycling, Environmental and Energy Systems Studies LTH Department of Technology and Society Faculty of Engineering at Lund University (submitted)
- id
- 9c0db464-15ea-41fd-82cb-5031a30b2560 (old id 546409)
- date added to LUP
- 2016-04-04 10:26:04
- date last changed
- 2018-11-21 20:58:44
@phdthesis{9c0db464-15ea-41fd-82cb-5031a30b2560, abstract = {{Anaerobic digestion and the production of biogas can provide an efficient means of meeting several objectives concerning energy, environmental and waste management policy. Interest in biogas is increasing, and new facilities are being built. There is a wide range of potential raw material, and both the biogas and digestates produced can be used in many different applications. The variation in raw materials and digestion processes contributes to the flexibility of biogas production systems, but at the same time makes their analysis and comparison more complicated.<br/><br> <br/><br> In this thesis, the energy performance in the life cycle of biogas production is assessed, as well as the environmental impact of introducing biogas systems to replace various fuels and existing strategies for the handling of various raw materials. The energy performance and environmental impact vary greatly between the biogas systems studied depending on the raw material digested and the reference system replaced. The results are largely dependent on the methodological assumptions made, for example, concerning focus, system boundaries, and how the energy required in joint operations is allocated to the raw materials digested. Many of the environmental implications depend on how changes resulting from non-energy-related aspects of the implementation of biogas production can be taken into account. For example, changes in emission of methane and ammonia from the handling of the raw material or changes in nitrogen leaching from arable land.<br/><br> <br/><br> There are several potential barriers to the successful implementation of biogas production. The aspect to which most attention was devoted here was the prospect of using digestate from large-scale biogas plants as a fertilizer in agriculture. Reliable and generally accepted disposal of the comparatively large amounts of digestate produced is necessary if biogas production is to be implemented. Agriculture is currently the most common, and sometimes the only suitable means of disposal of the digestate. Serious resistance to or problems associated with this use could therefore jeopardise the development of biogas systems.}}, author = {{Berglund, Maria}}, isbn = {{91-88360-80-6}}, keywords = {{Energiforskning; Energy research; indirect environmental impact; fuel-cycle emissions; environmental systems analysis; energy systems analysis; energy balance; digestate; Anaerobic digestion; biogas}}, language = {{eng}}, publisher = {{Environmental and Energy Systems Studies, Lund university}}, school = {{Lund University}}, title = {{Biogas production from a systems analytical perspective}}, url = {{https://lup.lub.lu.se/search/files/5538058/546411.pdf}}, year = {{2006}}, }