Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery

›› 2008, Vol. 16 ›› Issue (3): 343-353.

Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery

Edgar G. Hertwich^1,2, Martin Aaberg^2,3, Bhawna Singh^1,2, Anders H. StrΦmman^1,2

1. Industrial Ecology Programme, Norwegian University of Technology(NTNU), 7491 Trondheim, Norway;
2. Department of Energy and Process Engineering, Norwegian University of Technology (NTNU), 7491 Trondheim, Norway;
3. DNV Energy, Region Nordic and Eurasia, Veritasveien 11322 HΦvik, Norway

收稿日期:2007-07-02 修回日期:2008-05-05 出版日期:2008-06-28 发布日期:2008-06-28
通讯作者: Edgar G. Hertwich,E-mail:edgar.hertwich@ntnu.no

Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery

Edgar G. Hertwich^1,2, Martin Aaberg^2,3, Bhawna Singh^1,2, Anders H. StrΦmman^1,2

1. Industrial Ecology Programme, Norwegian University of Technology(NTNU), 7491 Trondheim, Norway;
2. Department of Energy and Process Engineering, Norwegian University of Technology (NTNU), 7491 Trondheim, Norway;
3. DNV Energy, Region Nordic and Eurasia, Veritasveien 11322 HΦvik, Norway

Received:2007-07-02 Revised:2008-05-05 Online:2008-06-28 Published:2008-06-28

摘要/Abstract

摘要： The development and deployment of Carbon dioxide Capture and Storage(CCS) technology is a cor-nerstone of the Norwegian government's climate strategy.A number of projects are currently evaluated/planned along the Norwegian West Coast,one at Tjeldbergodden.CO₂ from this project will be utilized in part for enhanced oil recovery in the Halten oil field,in the Norwegian Sea.We study a potential design of such a system.A combined cycle power plant with a gross power output of 832 MW is combined with CO₂ capture plant based on a post-combustion capture using amines as a solvent.The captured CO₂ is used for enhanced oil recovery(EOR).We employ a hybrid life-cycle assessment(LCA)method to assess the environmental impacts of the system.The study focuses on the modifications and operations of the platform during EOR.We allocate the impacts connected to the capture of CO₂ to electricity production,and the impacts connected to the transport and storage of CO₂ to the oil produced.Our study shows a substantial reduction of the greenhouse gas emissions from power production by 80% to 75 g·(kW·h)^-1.It also indicates a reduction of the emissions associated with oil production per unit oil produced, mostly due to the increased oil production.Reductions are especially significant if the additional power demand due to EOR leads to power supply from the land.

关键词: carbon dioxide capture and storage, enhanced oil recovery, offshore power supply, life-cycle analysis

Abstract: The development and deployment of Carbon dioxide Capture and Storage(CCS)technology is a cor-nerstone of the Norwegian government's climate strategy.A number of projects are currently evaluated/planned along the Norwegian West Coast,one at Tjeldbergodden.CO₂ from this project will be utilized in part for enhanced oil recovery in the Halten oil field,in the Norwegian Sea.We study a potential design of such a system.A combined cycle power plant with a gross power output of 832 MW is combined with CO₂ capture plant based on a post-combustion capture using amines as a solvent.The captured CO₂ is used for enhanced oil recovery(EOR).We employ a hybrid life-cycle assessment(LCA) method to assess the environmental impacts of the system.The study focuses on the modifications and operations of the platform during EOR.We allocate the impacts connected to the capture of CO₂ to electricity production,and the impacts connected to the transport and storage of CO₂ to the oil produced.Our study shows a substantial reduction of the greenhouse gas emissions from power production by 80% to 75 g·(kW·h)^-1.It also indicates a reduction of the emissions associated with oil production per unit oil produced, mostly due to the increased oil production.Reductions are especially significant if the additional power demand due to EOR leads to power supply from the land.

Key words: carbon dioxide capture and storage, enhanced oil recovery, offshore power supply, life-cycle analysis

Edgar G. Hertwich, Martin Aaberg, Bhawna Singh, Anders H. StrΦmman. Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery[J]. , 2008, 16(3): 343-353.

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Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery

Life-cycle Assessment of Carbon Dioxide Capture for Enhanced Oil Recovery

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