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利用热力学平衡常数理论计算了CO2埋存条件下的油井水泥石水化产物相关纯矿物受腐蚀的热力学条件,并比较了其耐腐蚀性能。利用Gibbs自由能最小化原理计算和分析了水泥石受腐蚀过程中水化产物的变化。结果表明:水化产物相关纯矿物或端元组分的耐腐蚀性能不同,优劣次序为4Mg(OH)2·2Al(OH)3·3H_2O、0.83CaO·0.67SiO2·1.83H_2O、0.67CaO·SiO2·1.5H_2O、6CaO·Al_2O3·3SO4·32H_2O、6CaO·Al_2O3·3SO4·30H_2O、1.33CaO·SiO2·2.17H_2O、3CaO·0.5Al_2O3·0.5Fe_2O3·0.84SiO2·4.32H_2O、3CaO·Fe_2O3·0.84SiO2·4.32H_2O、1.5CaO·0.67SiO2·2.5H_2O、Ca(OH)2;水泥石腐蚀时各水化产物被腐蚀的次序不同,先后次序为Ca(OH)2、水化硅酸钙固溶体、硅水榴石固溶体、钙矾石固溶体、4Mg(OH)2·2Al(OH)3·3H_2O;固溶体被腐蚀时不但质量减少,端元组分的摩尔数和比例也发生变化,但变化不完全受端元组分相对耐腐蚀性能控制。
Abstract:For the degradation of oil well set-cement under CO2 sequestration condition,the thermodynamic conditions of pure minerals related to hydration products degradation were determined based on the equilibrium constant theory,and the resistance difference was investigated.The mass change of hydration products was simulated based on the Gibbs free energy minimization principle.The results show that the order of degradation resistance of related pure minerals or end members is 4Mg(OH)2·2 Al(OH)3·3 H2 O,0.83 CaO·0.67SiO2·1.83H2 O,0.67CaO·SiO2·1.5H_2O,6CaO·Al_2O3·3SO4·32H2 O,6CaO·Al_2O3·3SO4·30 H_2O,1.33CaO·SiO2·2.17 H2 O,3 CaO·0.5 Al2 O3·0.5Fe2 O3·0.84SiO2·4.32H2 O,3CaO·Fe_2O3·0.84SiO2.4.32H2 O,1.5CaO·0.67SiO2·2.5H_2O,Ca(OH)2.The order of mass decrease in set-cement degradation process is Ca(OH)2,calcium silicate hydrate solid solution,Si-hydrogarnet solid solution,ettringite solid solution,and M4 AH10.The number of moles and the proportion of end member minerals changes and the quality of solid solution decreases,but the change is inconsistent with its relative degradation resistance.
[1]沈平平,杨永智.温室气体在石油开采中资源化利用的科学问题[J].中国基础科学, 2006, 8(3):23 31.SHEN Pingping, YANG Yongzhi. Chin Bas Sci(in Chinese), 2006,8(3):23 31.
[2] BACHU S. CO2 storage in geological media:role, means, status, and barriers to deployment[J]. Prog Energ Combust, 2008, 34(2):254 273.
[3]张二勇,李旭峰,何锦,等.地下咸水层封存CO2的关键技术研究[J].地下水, 2009, 31(3):15 19.ZHANG Eryong, LI Xufeng, HE Jin, et al. Ground Water(in Chinese),2009, 31(3):15 19.
[4] KUTCHKO B G, STRAZISAR B R, DZOMBAK D A, et al.Degradation of well cement by CO2 under geologic sequestration conditions[J]. Environ Sci Technol, 2007, 41(13):4787 4792.
[5]张旭辉,郑委,刘庆杰. CO2地质埋存后的逃逸问题研究进展[J].力学进展, 2010, 40(5):517 527.ZHANG Xuhui, ZHENG Wei, LIU Qingjie. Adv Mech(in Chinese),2010, 40(5):517 527.
[6] KUTCHKO B G, STRAZISAR B R, LOWRY G V, et al. Rate of CO2attack on hydrated Class H well cement under geologic sequestration conditions[J]. Environ Sci Technol, 2008, 42(16):6237 6242.
[7] RIMMELéG, BARLET-GOUéDARD V, PORCHERIE O, et al.Heterogeneous porosity distribution in Portland cement exposed to CO2-rich?uids[J]. Cem Concr Res, 2008, 38(8):1038 1048.
[8] DUGUID A, SCHERER G W. Degradation of oilwell cement due to exposure to carbonated brine[J]. Int J Green Gas Con, 2010, 4(3):546 560.
[9] SAUKI A, IRAWAN S. Effects of pressure and temperature on well cement degradation by supercritical CO2[J]. Int J Eng Tech, 2010,10(4):53 61.
[10] LI Q, LIM Y M, FLORES K M, et al. Chemical reactions of Portland Cement with aqueous CO2 and their impacts on cement’s mechanical properties under geologic CO2sequestration conditions[J]. Environ Sci Technol, 2015, 49(10):6335 6343.
[11] GUO J, CAO B, STEEFEL C I, et al. Effects of sulfate and magnesium on cement degradation under geologic CO2 sequestration conditions[J].Int J Green Gas Contr, 2017, 63:118 125.
[12]辜涛.二氧化碳地质封存条件下固井水泥石腐蚀损伤与防护研究[D].西南石油大学, 2017.GU Tao. Study on degradation of oilwell cement and anticorrosion technology under CO2 geological storage conditions(in Chinese,dissertation). Chengdu:Southwest Petroleum University, 2017.
[13]姚晓. CO2对油井水泥石的腐蚀:热力学条件、腐蚀机理及防护措施[J].西南石油学院学报, 1998, 20(3):68 71.YAO Xiao. J Southwest Petrol Inst(in Chinese), 1998, 20(3):68 71.
[14]姚晓,唐明述.油井水泥石CO2腐蚀的热力学条件[J].油田化学,1999, 16(1):10 13.YAO Xiao, TANG Mingshu. Oilfield Chem(in Chinese), 1999, 16(1):10 13.
[15] SHI Z, LOTHENBACH B, GEIKER M R, et al. Experimental studies and thermodynamic modeling of the carbonation of Portland cement,metakaolin and limestone mortars[J]. Cem Concr Res, 2016, 88:60 72.
[16] KUNTHER W, LOTHENBACH B, SCRIVENER K. Influence of bicarbonate ions on the deterioration of mortar bars in sulfate solutions[J]. Cem Concr Res, 2013, 44:77 86.
[17]傅献彩,沈文霞,姚天扬,等.物理化学上册(第五版)[M].北京:高等教育出版社, 2005:204 393.
[18] KULIK D A, WAGNER T, DMYTRIEVA S V, et al. GEM-Selektor geochemical modeling package:Revised algorithm and GEMS3K numerical kernel for coupled simulation codes[J]. Comput Geosci,2013, 17(1):1 24.
[19] LOTHENBACH B, KULIK D A, MATSCHEI T, et al. Cemdata18:A chemical thermodynamic database for hydrated Portland cements and alkali-activated materials[J]. Cem Concr Res, 2019, 115:472 506.
[20]刘崇建,黄柏宗,徐同台,等.油气井注水泥理论与应用[M].北京:石油工业出版社, 2001:6 72.
基本信息:
DOI:10.14062/j.issn.0454-5648.20200114
中图分类号:TE256;X701
引用信息:
[1]郭辛阳,宋雨媛,吴广军,等.二氧化碳埋存条件下油井水泥石腐蚀的热力学分析[J].硅酸盐学报,2020,48(08):1233-1239.DOI:10.14062/j.issn.0454-5648.20200114.
基金信息:
国家自然科学基金项目(51704325,51704321);; 中央高校基本科研业务费专项(18CX02103A)
2020-06-23
2020-06-23
2020-06-23