Assessing the potential contribution of excess heat from biogas plants towards decarbonising residential heating

Research output: Contribution to journalJournal article – Annual report year: 2019Researchpeer-review

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Assessing the potential contribution of excess heat from biogas plants towards decarbonising residential heating. / Weinand, Jann Michael; McKenna, Russell; Karner, Katharina; Braun, Lorenz; Herbes, Carsten.

In: Journal of Cleaner Production, Vol. 238, 117756, 2019.

Research output: Contribution to journalJournal article – Annual report year: 2019Researchpeer-review

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@article{d7c1104cad04481f9ebe4176fcc57973,
title = "Assessing the potential contribution of excess heat from biogas plants towards decarbonising residential heating",
abstract = "This paper analyses the technical potential for utilising excess heat from biogas plants, in order to supply local settlements through district heating. Based on a survey of around 600 biogas plant operators, the fractions of excess heat from the cogeneration units in these plants are analysed. A heuristic is developed to match biogas plants (heat sources) with local settlements (heat sinks) in order to determine a least-cost district heating supply for residential buildings. Two criteria are employed, namely the CO2 abatement costs and the payback period, which represent the macro- and microeconomic perspectives respectively. Based on the survey, the mean fraction of excess heat is 40{\%}, which is in agreement with other empirical studies. Extrapolating this fraction to the German biogas plant stock, which is selected as a case study, leads to technically feasible CO2 savings of around 2.5 MtCO2/a. Employing the criteria of CO2 abatement costs and payback period yields about 2 MtCO2/a below CO2 abatement costs of 200 €/tCO2 and below a payback period of 9 years. This represents about 0.25{\%} of the total German CO2 emissions in 2016 or around 2.5{\%} of all CO2 in residential buildings. Alternative threshold values of 80 €/tCO2 and 5 years payback period reduce the carbon reduction potential to about 0.5 MtCO2 and 0.75 MtCO2 respectively. These relatively high average costs are related to the typically low population density in rural regions where biogas plants are located. These potentials are concentrated in around 3,500 of 11,400 municipalities, where district heating from biogas plants could reduce CO2 emissions per capita by an average of 250 kgCO2/a and cover 12{\%} of the total heating demand. Apart from a methodology that can be transferred to any country with comparable data availability, the present study demonstrates that the use of excess heat in biogas plants can contribute to global decarbonisation.",
keywords = "Biogas plant, CO abatement costs, District heating, Energy autonomy, Excess heat",
author = "Weinand, {Jann Michael} and Russell McKenna and Katharina Karner and Lorenz Braun and Carsten Herbes",
year = "2019",
doi = "10.1016/j.jclepro.2019.117756",
language = "English",
volume = "238",
journal = "Journal of Cleaner Production",
issn = "0959-6526",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Assessing the potential contribution of excess heat from biogas plants towards decarbonising residential heating

AU - Weinand, Jann Michael

AU - McKenna, Russell

AU - Karner, Katharina

AU - Braun, Lorenz

AU - Herbes, Carsten

PY - 2019

Y1 - 2019

N2 - This paper analyses the technical potential for utilising excess heat from biogas plants, in order to supply local settlements through district heating. Based on a survey of around 600 biogas plant operators, the fractions of excess heat from the cogeneration units in these plants are analysed. A heuristic is developed to match biogas plants (heat sources) with local settlements (heat sinks) in order to determine a least-cost district heating supply for residential buildings. Two criteria are employed, namely the CO2 abatement costs and the payback period, which represent the macro- and microeconomic perspectives respectively. Based on the survey, the mean fraction of excess heat is 40%, which is in agreement with other empirical studies. Extrapolating this fraction to the German biogas plant stock, which is selected as a case study, leads to technically feasible CO2 savings of around 2.5 MtCO2/a. Employing the criteria of CO2 abatement costs and payback period yields about 2 MtCO2/a below CO2 abatement costs of 200 €/tCO2 and below a payback period of 9 years. This represents about 0.25% of the total German CO2 emissions in 2016 or around 2.5% of all CO2 in residential buildings. Alternative threshold values of 80 €/tCO2 and 5 years payback period reduce the carbon reduction potential to about 0.5 MtCO2 and 0.75 MtCO2 respectively. These relatively high average costs are related to the typically low population density in rural regions where biogas plants are located. These potentials are concentrated in around 3,500 of 11,400 municipalities, where district heating from biogas plants could reduce CO2 emissions per capita by an average of 250 kgCO2/a and cover 12% of the total heating demand. Apart from a methodology that can be transferred to any country with comparable data availability, the present study demonstrates that the use of excess heat in biogas plants can contribute to global decarbonisation.

AB - This paper analyses the technical potential for utilising excess heat from biogas plants, in order to supply local settlements through district heating. Based on a survey of around 600 biogas plant operators, the fractions of excess heat from the cogeneration units in these plants are analysed. A heuristic is developed to match biogas plants (heat sources) with local settlements (heat sinks) in order to determine a least-cost district heating supply for residential buildings. Two criteria are employed, namely the CO2 abatement costs and the payback period, which represent the macro- and microeconomic perspectives respectively. Based on the survey, the mean fraction of excess heat is 40%, which is in agreement with other empirical studies. Extrapolating this fraction to the German biogas plant stock, which is selected as a case study, leads to technically feasible CO2 savings of around 2.5 MtCO2/a. Employing the criteria of CO2 abatement costs and payback period yields about 2 MtCO2/a below CO2 abatement costs of 200 €/tCO2 and below a payback period of 9 years. This represents about 0.25% of the total German CO2 emissions in 2016 or around 2.5% of all CO2 in residential buildings. Alternative threshold values of 80 €/tCO2 and 5 years payback period reduce the carbon reduction potential to about 0.5 MtCO2 and 0.75 MtCO2 respectively. These relatively high average costs are related to the typically low population density in rural regions where biogas plants are located. These potentials are concentrated in around 3,500 of 11,400 municipalities, where district heating from biogas plants could reduce CO2 emissions per capita by an average of 250 kgCO2/a and cover 12% of the total heating demand. Apart from a methodology that can be transferred to any country with comparable data availability, the present study demonstrates that the use of excess heat in biogas plants can contribute to global decarbonisation.

KW - Biogas plant

KW - CO abatement costs

KW - District heating

KW - Energy autonomy

KW - Excess heat

U2 - 10.1016/j.jclepro.2019.117756

DO - 10.1016/j.jclepro.2019.117756

M3 - Journal article

VL - 238

JO - Journal of Cleaner Production

JF - Journal of Cleaner Production

SN - 0959-6526

M1 - 117756

ER -