超临界状态CO_2封存技术研究进展
|
摘要
详细介绍了超临界CO_2的物化性质及其与地层水和矿物的作用,并详述了其基本工艺流程、封存机理、封存类型及影响因素,通过对国内外研究现状进行对比和综合分析,指出其在诸多方面的优势,同时从不同角度阐述了超临界二氧化碳封存技术面临的挑战和问题,并指出研发多技术联合的新型封存技术为下阶段的发展目标。
The physicochemical properties of supercritical carbon dioxide and its interaction with formation water and minerals are introduced in detail. The basic process flow,storage mechanism,storage type and influencing factors are detailed. Through comparison and comprehensive analysis of domestic and foreign research status,it is pointed out its advantages in many aspects,while expounding the challenges and problems of supercritical carbon dioxide storage technology from different angles,and pointed out that the development of multi-technology joint new storage technology for the next stage of development goals.
The physicochemical properties of supercritical carbon dioxide and its interaction with formation water and minerals are introduced in detail. The basic process flow,storage mechanism,storage type and influencing factors are detailed. Through comparison and comprehensive analysis of domestic and foreign research status,it is pointed out its advantages in many aspects,while expounding the challenges and problems of supercritical carbon dioxide storage technology from different angles,and pointed out that the development of multi-technology joint new storage technology for the next stage of development goals.
引文
[1]吴绍洪.地球升温4摄氏度若不干预CO2含量将比工业化前翻倍[J].黑龙江科技信息,2014(1):14-16.
[2]孙健.控制气候变化的国际法律机制研究[D].哈尔滨:东北林业大学,2010.
[3]李敏洁.超临界二氧化碳萃取在石油工业中的应用探究[J].当代化工,2016,45(5):954-956.
[4]冯金禹,闫铁,孙士慧,等.超临界二氧化碳钻井技术的研究进展[J].现代化工,2018,38(6):11-14.
[5]李发旺,李赞忠.超临界流体技术及应用现状[J].内蒙古石油化工,2014,40(23):92-94.
[6]单金玲.超临界CO2管内冷却换热的理论模拟与实验研究[D].北京:华北电力大学,2014.
[7]孟庆亮.超临界二氧化碳在盐水层多孔介质条件下迁移的数值模拟研究[D].合肥:中国科学技术大学,2014.
[8] Peter J Cook. Research and development of carbon capture and storage technologies and future deployment of clean energy industries———lessons learned in Australia over the past 20 years[J]. Engineering,2017,3(4):103-121.
[9] Damen K,van Troost M,Faaij A,et al. A comparison of electricity and hydrogen production systems with CO2capture and storage-Part B:Chain analysis of promising CCS options[J]. Progress Energy Combust Sci,2007,33(6):580-609.
[10] Hiair S,Ozaki K,Tabe Y,et al. Numerical simulation for dissolution of liquid CO2droplets covered with clathrate film in intermediate depth of ocean[J]. Energy Conversion and Management,1997,38:S313-S318.
[11] David J,Herzog H. The cost of carbon capture[C]∥Fifth international conference of greenhouse gas control technologies. Cairns,Australia:CSIRO,Collingwood,2001.
[12] Akimoto K,Takagi M,Tomoda T. Economic evaluation of the geological storage of CO2considering the scale of economy[J]. International Journal of Greenhouse Gas Control,2007,1(2):271-279.
[13] McCoy S T. The economics of CO2transport by pipeline and storage in saline aquifer and oil reservoirs[C]. PA,USA:Carnegie Mellon University,2008.
[14] Adamczyk K,Premont-Schwarz M,Pines D,et al. Realtime observation of carbonic acid formation in aqueous solution[J]. Science,2009,326:1690-1694.
[15]王萍,王炳才.我国碳捕集与封存技术发展概况[J].天津商业大学学报,2016,36(4):57-63.
[16]刘嘉,李永,刘德顺.碳封存技术的现状及在中国应用的研究意义[J].环境与可持续发展,2009,34(2):33-35.
[17]吴倩.不确定性条件下的区域碳捕集与封存系统优化研究[D].北京:华北电力大学,2014.
[18]刘烨.二氧化碳封存储层影响因素分析———效果预测以及4D地震监测可行性分析[D].西安:西北大学,2012.
[19]李健,许楠希.碳捕集与封存项目的经济性评价[J].科技管理研究,2012(8):203-206.
[20]霍传林.我国近海二氧化碳海底封存潜力评估和封存区域研究[D].大连:大连海事大学,2014.
[21]匡建超,王众,霍志磊.中国二氧化碳捕捉与封存(CCS)技术早期实施方案构建研究[J].中外能源,2012(12):17-22.
[22]王小丰.探究CO2捕集,运输和封存技术的现状、发展与挑战[J].当代化工研究,2017(5):111-112.
[23]魏巍,朱筱敏,国殿斌,等.查干凹陷下白垩统砂岩储层碳酸盐胶结物成岩期次及形成机理[J].地球化学,2015,44(6):590-599.
[24]王秀宇,杨胜来,杨永忠,等. CO2封存和提高采收率过程中岩石与饱和水的CO2反应研究[J].钻采工艺,2015,38(3):87-90,14.
[25]李勇.用超临界二氧化碳改造水泥基建材的理论和试验研究[D].哈尔滨:哈尔滨工业大学,2012.
[2]孙健.控制气候变化的国际法律机制研究[D].哈尔滨:东北林业大学,2010.
[3]李敏洁.超临界二氧化碳萃取在石油工业中的应用探究[J].当代化工,2016,45(5):954-956.
[4]冯金禹,闫铁,孙士慧,等.超临界二氧化碳钻井技术的研究进展[J].现代化工,2018,38(6):11-14.
[5]李发旺,李赞忠.超临界流体技术及应用现状[J].内蒙古石油化工,2014,40(23):92-94.
[6]单金玲.超临界CO2管内冷却换热的理论模拟与实验研究[D].北京:华北电力大学,2014.
[7]孟庆亮.超临界二氧化碳在盐水层多孔介质条件下迁移的数值模拟研究[D].合肥:中国科学技术大学,2014.
[8] Peter J Cook. Research and development of carbon capture and storage technologies and future deployment of clean energy industries———lessons learned in Australia over the past 20 years[J]. Engineering,2017,3(4):103-121.
[9] Damen K,van Troost M,Faaij A,et al. A comparison of electricity and hydrogen production systems with CO2capture and storage-Part B:Chain analysis of promising CCS options[J]. Progress Energy Combust Sci,2007,33(6):580-609.
[10] Hiair S,Ozaki K,Tabe Y,et al. Numerical simulation for dissolution of liquid CO2droplets covered with clathrate film in intermediate depth of ocean[J]. Energy Conversion and Management,1997,38:S313-S318.
[11] David J,Herzog H. The cost of carbon capture[C]∥Fifth international conference of greenhouse gas control technologies. Cairns,Australia:CSIRO,Collingwood,2001.
[12] Akimoto K,Takagi M,Tomoda T. Economic evaluation of the geological storage of CO2considering the scale of economy[J]. International Journal of Greenhouse Gas Control,2007,1(2):271-279.
[13] McCoy S T. The economics of CO2transport by pipeline and storage in saline aquifer and oil reservoirs[C]. PA,USA:Carnegie Mellon University,2008.
[14] Adamczyk K,Premont-Schwarz M,Pines D,et al. Realtime observation of carbonic acid formation in aqueous solution[J]. Science,2009,326:1690-1694.
[15]王萍,王炳才.我国碳捕集与封存技术发展概况[J].天津商业大学学报,2016,36(4):57-63.
[16]刘嘉,李永,刘德顺.碳封存技术的现状及在中国应用的研究意义[J].环境与可持续发展,2009,34(2):33-35.
[17]吴倩.不确定性条件下的区域碳捕集与封存系统优化研究[D].北京:华北电力大学,2014.
[18]刘烨.二氧化碳封存储层影响因素分析———效果预测以及4D地震监测可行性分析[D].西安:西北大学,2012.
[19]李健,许楠希.碳捕集与封存项目的经济性评价[J].科技管理研究,2012(8):203-206.
[20]霍传林.我国近海二氧化碳海底封存潜力评估和封存区域研究[D].大连:大连海事大学,2014.
[21]匡建超,王众,霍志磊.中国二氧化碳捕捉与封存(CCS)技术早期实施方案构建研究[J].中外能源,2012(12):17-22.
[22]王小丰.探究CO2捕集,运输和封存技术的现状、发展与挑战[J].当代化工研究,2017(5):111-112.
[23]魏巍,朱筱敏,国殿斌,等.查干凹陷下白垩统砂岩储层碳酸盐胶结物成岩期次及形成机理[J].地球化学,2015,44(6):590-599.
[24]王秀宇,杨胜来,杨永忠,等. CO2封存和提高采收率过程中岩石与饱和水的CO2反应研究[J].钻采工艺,2015,38(3):87-90,14.
[25]李勇.用超临界二氧化碳改造水泥基建材的理论和试验研究[D].哈尔滨:哈尔滨工业大学,2012.