二氧化碳環境下對油井水泥物理性質及化學性質之影響

綜合許多提出CO2封存技術的研究中,因地質封存具有巨大潛在的儲存量,因此將CO2注入地底封存為最有遠景的方式。然而評估保護井孔的油井水泥在長期的封存下是否能安全且有效的封存CO2為我們必須做的一項課題。CO2注入到深層的地質結構中通常伴隨著含水層或鹽水層,CO2與水會結合形成碳酸(H2CO3)並且使水泥鹼性降低、抗壓強度降低、滲透率增加,這些可能會造成CO2從井孔洩漏的風險。 本研究試圖研究不同配比的API G級水泥在CO2環境下(常壓、70℃)對其力學性質、化學組成、微觀結構之影響。添加物包含飛灰、膨潤土、矽粉及重晶石。連續反應28天後進行試驗,力學試驗部分包括抗壓強度、彈性參數,微觀結構分...

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Main Authors: 李冠穎, Lee, Kuan-Yin
Other Authors: 資源工程學系碩博士班, 王建力, Wang, Chein-Lee
Format: Thesis
Language:Chinese
English
Published: 2011
Subjects:
Carbonic acid
Online Access:http://ir.lib.ncku.edu.tw/handle/987654321/116079
http://ir.lib.ncku.edu.tw/bitstream/987654321/116079/-1/index.html
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spelling ftchengkunguniv:oai:ir.lib.ncku.edu.tw:987654321/116079 2023-05-15T15:53:06+02:00 二氧化碳環境下對油井水泥物理性質及化學性質之影響 A study of the mechanical and chemical properties of API G cement with additives exposed to CO2- rich environment 李冠穎 Lee, Kuan-Yin 資源工程學系碩博士班 王建力 Wang, Chein-Lee 2011-05-27 http://ir.lib.ncku.edu.tw/handle/987654321/116079 http://ir.lib.ncku.edu.tw/bitstream/987654321/116079/-1/index.html Chi en_US chi eng thesis 2011 ftchengkunguniv 2016-05-22T07:33:31Z 綜合許多提出CO2封存技術的研究中,因地質封存具有巨大潛在的儲存量,因此將CO2注入地底封存為最有遠景的方式。然而評估保護井孔的油井水泥在長期的封存下是否能安全且有效的封存CO2為我們必須做的一項課題。CO2注入到深層的地質結構中通常伴隨著含水層或鹽水層,CO2與水會結合形成碳酸(H2CO3)並且使水泥鹼性降低、抗壓強度降低、滲透率增加,這些可能會造成CO2從井孔洩漏的風險。 本研究試圖研究不同配比的API G級水泥在CO2環境下(常壓、70℃)對其力學性質、化學組成、微觀結構之影響。添加物包含飛灰、膨潤土、矽粉及重晶石。連續反應28天後進行試驗,力學試驗部分包括抗壓強度、彈性參數,微觀結構分析包括XRD、SEM、EDS,也觀察記錄了試體的碳化深度。本研究發現添加飛灰的API G級水泥有最佳的抗壓強度且有最深的碳酸鈣堆積層,添加膨潤土的API G級水泥因水灰比較高所以其抗壓強度最弱且碳酸鈣堆積層深度較淺。 Among commonly proposed CO2 storage techniques injection of anthropogenic CO2 underground is promising due to their large potential storage capacity and geographic ubiquity However the long-term wellbore integrity of the cement sheath should be carefully evaluated to ensure the safe and efficient storage of CO2 Injection of CO2 into the deep geological formations often encounters the aquifers or deep saline aquifers CO2 reacting with water will become the carbonic acid (H2CO3) and it will make cement more alkaline lower in compressive strength and increasing in degree of saturation The well integrity will be weakened by the increase in the degree of carbonization It will result in the reduction in service life of the well and possible leakage of CO2 from the wellbore This paper attempts to study the mechanical properties chemical compositions and microscopic structures of API G cements with different additives in the saturated-CO2 condition (atmospheric pressure 70℃) The additives under investigation include fly ash bentonite and barite with silicate The evolution of the mechanical properties including compressive strength deformation modulus and microscopic structure analysis including XRD EDS and SEM were recorded over a period of 28 days The carbonized depths of the samples over time were also observed This study finds that the API G cement with fly ash displays the best compressive strength with deepest penetrating depth of carbonization The API G cement with bentonite with higher water content has the lowest compressive strength with shallowest penetrating depth of carbonization Thesis Carbonic acid National Cheng Kung University: NCKU Institutional Repository
institution Open Polar
collection National Cheng Kung University: NCKU Institutional Repository
op_collection_id ftchengkunguniv
language Chinese
English
description 綜合許多提出CO2封存技術的研究中,因地質封存具有巨大潛在的儲存量,因此將CO2注入地底封存為最有遠景的方式。然而評估保護井孔的油井水泥在長期的封存下是否能安全且有效的封存CO2為我們必須做的一項課題。CO2注入到深層的地質結構中通常伴隨著含水層或鹽水層,CO2與水會結合形成碳酸(H2CO3)並且使水泥鹼性降低、抗壓強度降低、滲透率增加,這些可能會造成CO2從井孔洩漏的風險。 本研究試圖研究不同配比的API G級水泥在CO2環境下(常壓、70℃)對其力學性質、化學組成、微觀結構之影響。添加物包含飛灰、膨潤土、矽粉及重晶石。連續反應28天後進行試驗,力學試驗部分包括抗壓強度、彈性參數,微觀結構分析包括XRD、SEM、EDS,也觀察記錄了試體的碳化深度。本研究發現添加飛灰的API G級水泥有最佳的抗壓強度且有最深的碳酸鈣堆積層,添加膨潤土的API G級水泥因水灰比較高所以其抗壓強度最弱且碳酸鈣堆積層深度較淺。 Among commonly proposed CO2 storage techniques injection of anthropogenic CO2 underground is promising due to their large potential storage capacity and geographic ubiquity However the long-term wellbore integrity of the cement sheath should be carefully evaluated to ensure the safe and efficient storage of CO2 Injection of CO2 into the deep geological formations often encounters the aquifers or deep saline aquifers CO2 reacting with water will become the carbonic acid (H2CO3) and it will make cement more alkaline lower in compressive strength and increasing in degree of saturation The well integrity will be weakened by the increase in the degree of carbonization It will result in the reduction in service life of the well and possible leakage of CO2 from the wellbore This paper attempts to study the mechanical properties chemical compositions and microscopic structures of API G cements with different additives in the saturated-CO2 condition (atmospheric pressure 70℃) The additives under investigation include fly ash bentonite and barite with silicate The evolution of the mechanical properties including compressive strength deformation modulus and microscopic structure analysis including XRD EDS and SEM were recorded over a period of 28 days The carbonized depths of the samples over time were also observed This study finds that the API G cement with fly ash displays the best compressive strength with deepest penetrating depth of carbonization The API G cement with bentonite with higher water content has the lowest compressive strength with shallowest penetrating depth of carbonization
author2 資源工程學系碩博士班
王建力
Wang, Chein-Lee
format Thesis
author 李冠穎
Lee, Kuan-Yin
spellingShingle 李冠穎
Lee, Kuan-Yin
二氧化碳環境下對油井水泥物理性質及化學性質之影響
author_facet 李冠穎
Lee, Kuan-Yin
author_sort 李冠穎
title 二氧化碳環境下對油井水泥物理性質及化學性質之影響
title_short 二氧化碳環境下對油井水泥物理性質及化學性質之影響
title_full 二氧化碳環境下對油井水泥物理性質及化學性質之影響
title_fullStr 二氧化碳環境下對油井水泥物理性質及化學性質之影響
title_full_unstemmed 二氧化碳環境下對油井水泥物理性質及化學性質之影響
title_sort 二氧化碳環境下對油井水泥物理性質及化學性質之影響
publishDate 2011
url http://ir.lib.ncku.edu.tw/handle/987654321/116079
http://ir.lib.ncku.edu.tw/bitstream/987654321/116079/-1/index.html
genre Carbonic acid
genre_facet Carbonic acid
_version_ 1766388151815766016

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