Techno-economic prospects for CO2 capture from distributed energy systems, , 19(March 2013), 2013, pp. 328-347

T. Kuramochi; C.A. Ramirez; W.C. Turkenburg; A.P.C. Faaij

doi:10.1016/j.rser.2012.10.051

Techno-economic prospects for CO2 capture from distributed energy systems, , 19(March 2013), 2013, pp. 328-347

T. Kuramochi, C.A. Ramirez, W.C. Turkenburg, A.P.C. Faaij

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

CO2 emissions from distributed energy systems are expected to become increasingly significant, accounting for about 20% for current global energy-related CO2 emissions in 2030. This article reviews, assesses and compares the techno-economic performance of CO2 capture from distributed energy systems taking into account differences in timeframe, fuel type and energy plant type. The analysis includes the energy plant, CO2 capture and compression, and distributed transport between the capture site and a trunk pipeline. Key parameters, e.g., capacity factor, energy prices and interest rate, were normalized for the performance comparison. The findings of this study indicate that in the short-mid term (around 2020–2025), the energy penalty for CO2 capture ranges between 23% and 30% for coal-fired plants and 10–28% for natural gas-fired plants. Costs are between 30 and 140 h/tCO2 avoided for plant scales larger than 100 MWLHV (fuel input) and 50–150 h/tCO2 avoided for 10–100 MWLHV. In the long-term (2030 and beyond), the energy penalty for CO2 capture might reduce to between 4% and 9% and the costs to around 10–90 h/tCO2 avoided for plant scales larger than 100 MWLHV, 25–100 h/tCO2 avoided for 10–100 MWLHV and 35–150 h/tCO2 avoided for 10 MWLHV or smaller. CO2 compression and distributed transport costs are significant. For a distance of 30 km, 10 h/tCO2 transported was calculated for scales below 500 tCO2/day and more than 50 h/tCO2 transported for scales below 5 tCO2/day (equivalent to 1 MWLHV natural gas). CO2 compression is responsible for the largest share of these costs. CO2 capture from distributed energy systems is not prohibitively expensive and has a significant cost reduction potential in the long term. Distributed CO2 emission sources should also be considered for CCS, adding to the economies of scale of CO2 transport and storage, and optimizing the deployment of CCS. & 2012 Published by Elsevier Ltd

Original language	English
Pages (from-to)	328-347
Number of pages	20
Journal	Renewable and Sustainable Energy Reviews
Volume	19
Issue number	March 2013
DOIs	https://doi.org/10.1016/j.rser.2012.10.051
Publication status	Published - 2013

Keywords

CO2 capture
Techno-economic analysis
Distributed generation
CHP
Economies of scale
District heating

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.rser.2012.10.051

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title = "Techno-economic prospects for CO2 capture from distributed energy systems, , 19(March 2013), 2013, pp. 328-347",

abstract = "CO2 emissions from distributed energy systems are expected to become increasingly significant, accounting for about 20% for current global energy-related CO2 emissions in 2030. This article reviews, assesses and compares the techno-economic performance of CO2 capture from distributed energy systems taking into account differences in timeframe, fuel type and energy plant type. The analysis includes the energy plant, CO2 capture and compression, and distributed transport between the capture site and a trunk pipeline. Key parameters, e.g., capacity factor, energy prices and interest rate, were normalized for the performance comparison. The findings of this study indicate that in the short-mid term (around 2020–2025), the energy penalty for CO2 capture ranges between 23% and 30% for coal-fired plants and 10–28% for natural gas-fired plants. Costs are between 30 and 140 h/tCO2 avoided for plant scales larger than 100 MWLHV (fuel input) and 50–150 h/tCO2 avoided for 10–100 MWLHV. In the long-term (2030 and beyond), the energy penalty for CO2 capture might reduce to between 4% and 9% and the costs to around 10–90 h/tCO2 avoided for plant scales larger than 100 MWLHV, 25–100 h/tCO2 avoided for 10–100 MWLHV and 35–150 h/tCO2 avoided for 10 MWLHV or smaller. CO2 compression and distributed transport costs are significant. For a distance of 30 km, 10 h/tCO2 transported was calculated for scales below 500 tCO2/day and more than 50 h/tCO2 transported for scales below 5 tCO2/day (equivalent to 1 MWLHV natural gas). CO2 compression is responsible for the largest share of these costs. CO2 capture from distributed energy systems is not prohibitively expensive and has a significant cost reduction potential in the long term. Distributed CO2 emission sources should also be considered for CCS, adding to the economies of scale of CO2 transport and storage, and optimizing the deployment of CCS. & 2012 Published by Elsevier Ltd",

keywords = "CO2 capture, Techno-economic analysis, Distributed generation, CHP, Economies of scale, District heating",

author = "T. Kuramochi and C.A. Ramirez and W.C. Turkenburg and A.P.C. Faaij",

year = "2013",

doi = "10.1016/j.rser.2012.10.051",

language = "English",

volume = "19",

pages = "328--347",

journal = "Renewable and Sustainable Energy Reviews",

issn = "1364-0321",

publisher = "Elsevier Ltd",

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T1 - Techno-economic prospects for CO2 capture from distributed energy systems, , 19(March 2013), 2013, pp. 328-347

AU - Kuramochi, T.

AU - Ramirez, C.A.

AU - Turkenburg, W.C.

AU - Faaij, A.P.C.

PY - 2013

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N2 - CO2 emissions from distributed energy systems are expected to become increasingly significant, accounting for about 20% for current global energy-related CO2 emissions in 2030. This article reviews, assesses and compares the techno-economic performance of CO2 capture from distributed energy systems taking into account differences in timeframe, fuel type and energy plant type. The analysis includes the energy plant, CO2 capture and compression, and distributed transport between the capture site and a trunk pipeline. Key parameters, e.g., capacity factor, energy prices and interest rate, were normalized for the performance comparison. The findings of this study indicate that in the short-mid term (around 2020–2025), the energy penalty for CO2 capture ranges between 23% and 30% for coal-fired plants and 10–28% for natural gas-fired plants. Costs are between 30 and 140 h/tCO2 avoided for plant scales larger than 100 MWLHV (fuel input) and 50–150 h/tCO2 avoided for 10–100 MWLHV. In the long-term (2030 and beyond), the energy penalty for CO2 capture might reduce to between 4% and 9% and the costs to around 10–90 h/tCO2 avoided for plant scales larger than 100 MWLHV, 25–100 h/tCO2 avoided for 10–100 MWLHV and 35–150 h/tCO2 avoided for 10 MWLHV or smaller. CO2 compression and distributed transport costs are significant. For a distance of 30 km, 10 h/tCO2 transported was calculated for scales below 500 tCO2/day and more than 50 h/tCO2 transported for scales below 5 tCO2/day (equivalent to 1 MWLHV natural gas). CO2 compression is responsible for the largest share of these costs. CO2 capture from distributed energy systems is not prohibitively expensive and has a significant cost reduction potential in the long term. Distributed CO2 emission sources should also be considered for CCS, adding to the economies of scale of CO2 transport and storage, and optimizing the deployment of CCS. & 2012 Published by Elsevier Ltd

AB - CO2 emissions from distributed energy systems are expected to become increasingly significant, accounting for about 20% for current global energy-related CO2 emissions in 2030. This article reviews, assesses and compares the techno-economic performance of CO2 capture from distributed energy systems taking into account differences in timeframe, fuel type and energy plant type. The analysis includes the energy plant, CO2 capture and compression, and distributed transport between the capture site and a trunk pipeline. Key parameters, e.g., capacity factor, energy prices and interest rate, were normalized for the performance comparison. The findings of this study indicate that in the short-mid term (around 2020–2025), the energy penalty for CO2 capture ranges between 23% and 30% for coal-fired plants and 10–28% for natural gas-fired plants. Costs are between 30 and 140 h/tCO2 avoided for plant scales larger than 100 MWLHV (fuel input) and 50–150 h/tCO2 avoided for 10–100 MWLHV. In the long-term (2030 and beyond), the energy penalty for CO2 capture might reduce to between 4% and 9% and the costs to around 10–90 h/tCO2 avoided for plant scales larger than 100 MWLHV, 25–100 h/tCO2 avoided for 10–100 MWLHV and 35–150 h/tCO2 avoided for 10 MWLHV or smaller. CO2 compression and distributed transport costs are significant. For a distance of 30 km, 10 h/tCO2 transported was calculated for scales below 500 tCO2/day and more than 50 h/tCO2 transported for scales below 5 tCO2/day (equivalent to 1 MWLHV natural gas). CO2 compression is responsible for the largest share of these costs. CO2 capture from distributed energy systems is not prohibitively expensive and has a significant cost reduction potential in the long term. Distributed CO2 emission sources should also be considered for CCS, adding to the economies of scale of CO2 transport and storage, and optimizing the deployment of CCS. & 2012 Published by Elsevier Ltd

KW - CO2 capture

KW - Techno-economic analysis

KW - Distributed generation

KW - CHP

KW - Economies of scale

KW - District heating

U2 - 10.1016/j.rser.2012.10.051

DO - 10.1016/j.rser.2012.10.051

M3 - Article

SN - 1364-0321

VL - 19

SP - 328

EP - 347

JO - Renewable and Sustainable Energy Reviews

JF - Renewable and Sustainable Energy Reviews

IS - March 2013

ER -

Techno-economic prospects for CO2 capture from distributed energy systems, , 19(March 2013), 2013, pp. 328-347

Abstract

Keywords

UN SDGs

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