[1] 梁天成,刘云志,付海峰,等.多级循环泵注水力压裂模拟实验研究[J].岩土力学,2018,39(增刊1):355-361. LIANG Tiancheng,LIU Yunzhi,FU Haifeng,et al.Experimental study of hydraulic fracturing simulation for mutistage circulating pump injection[J].Rock and Soil Mechanics,2018,39(S1):355-361. [2] 陶云奇,刘东,许江,等.大尺寸复杂应力水力压裂裂缝扩展模拟试验研究[J].采矿与安全工程学报,2019,36(2):405-412. TAO Yunqi,LIU Dong,XU Jiang,et al.Experimental study on hydraulic fracturing propagation in coal/rock with large size and complex stress[J].Journal of Mining & Safety Engineering,2019,36(2):405-412. [3] 袁学浩,姚艳斌,甘泉,等.TOU GH-FLAC(3D)热流固耦合模拟煤储层水力压裂过程[J]. 石油与天然气地质,2018,39(3):611-619. YUAN Xuehao,YAO Yanbin,GAN Quan,et al.Investigation of hydraulic fracturing process in coal reservoir by a coupled thermo-hydro-mechanical simulator TOUGH-FLAC3D[J].Oil & Gas Geology,2018,39(3):611-619. [4] 赵瑜,何鹏飞.基于PPCZ模型的KGD水力压裂数值模拟[J].煤炭学报,2018, 43(10):210-219. ZHAO Yu,HE Pengfei.Numerical simulation of KGD hydraulic fracture based on PPCZ model[J].Journal of China Coal Society,2018,43(10):210-219. [5] 马耕,冯丹,陶云奇,等.顶板虚拟储层水力压裂物理模拟实验[J].煤矿安全,2018,49(2):1-4. MA Geng,FENG Dan,TAO Yunqi,et al.Physical simulation experiment of hydraulic fracturing for virtual reservoir in roof[J].Safety in Coal Mines,2018,49(2):1-4. [6] 葛燚.工艺参数对压裂效果影响的三维模拟分析[D].大连:大连理工大学,2018. GE Yi.Three-dimensional simulation analysis of the influence of process parameters on fracturing effect[D].Dalian:Dalian University of Technology,2018. [7] 张晟瑞.水力压裂微地震正演模拟分析及应用研究[D].大庆:东北石油大学,2018. ZHANG Shengrui.Analysis and application of micro seismic forward modeling of hydraulic fracturing[D].Daqing:Northeast Petroleum University,2018. [8] 杜书恒,庞姗,师永民.水力压裂缝动态非对称延伸过程数值模拟[J].油气地质与采收率,2018,25(4):106-114. DU Shuheng,PANG Shan,SHI Yongmin.Numerical simulation of dynamic asymmetric extension process in hydraulic fracturing[J].Petroleum Geology and Recovery Efficiency,2018,25(4):106-114. [9] 李小龙,李建雄,王涛,等.基于数值模拟的径向井压裂裂缝形态[J].大庆石油地质与开发,2018,37(3):90-95. LI Xiaolong,LI Jianxiong,WANG Tao,et al.Crack morphology of the radial well fracturing based on the numerical simulation[J].Petroleum Geology & Oilfield Development in Daqing,2018,37(3):90-95. [10] 任喜东,李咏洲.Z油田大斜度压裂井产能数值模拟研究[J].石油化工高等学校学报, 2018,31(2):76-81. REN Xidong,LI Yongzhou.Numerical simulation of large slope fracturing well productivity in Z Oilfield[J].Journal of Petrochemical Universities,2018,31(2):76-81. [11] 景国勋,王远声,周霏,等.基于RFPA(2D)的不同角度穿层钻孔水力压裂技术模拟研究[J].煤矿开采,2018,23(5):107-111. JING Guoxun,WANG Yuansheng,ZHOU Fei,et al.Numerical simulation study of water fracturing with different angle through beds holes based on RFPA2D[J].Coal Mining Technology,2018,23(5):107-111. [12] 吴奇,梁兴,鲜成钢,等.地质-工程一体化高效开发中国南方海相页岩气[J].中国石油勘探,2015,20(4):1-23. WU Qi,LIANG Xing,XIAN Chenggang,et al.Geoscience-to-production integration ensures effective and efficient South China Marine shale gas development[J].China Petroleum Exploration,2015,20(4):1-23. [13] 鲜成钢,张介辉,陈欣,等.地质力学在地质工程一体化中的应用[J].中国石油勘探,2017,22(1):75-88. XIAN Chenggang,ZHANG Jiehui,CHEN Xin,et al.Application of geomechanics in geology-engineering integration[J].China Petroleum Exploration,2017,22(1):75-88. [14] 黄浩勇,范宇,曾波,等.长宁区块页岩气水平井组地质工程一体化[J].科学技术与工程,2020,20(1):175-182. HUANG Haoyong,FAN Yu,ZENG Bo,et al.Geology-engineering Integration of Platform Well in Changning Block[J].Science Technology and Engineering,2020,20(1):175-182. [15] 延新杰.储层脆性对水力压裂裂缝复杂性影响的数值模拟研究[D].大连:大连理工大学,2018. YAN Xinjie.Numerical simulation study on the influence of reservoir brittleness on complexity of hydraulic fracture[D].Dalian:Dalian University of Technology,2018. [16] 党录瑞,周长林,黄媚,等.考虑多重滤失效应的前置液酸压有效缝长模拟[J].天然气工业,2018,38(7):65-72. DANG Lurui,ZHOU Changlin,HUANG Mei,et al.Simulation of effective fracture length of prepad acid fracturing considering multiple leak-off effect[J].Natural Gas Industry,2018,38(7):65-72. [17] 郭艳东,王卫红,刘华,等.页岩气多段压裂水平井产能影响因素研究[J].科技通报,2018,34(4):72-78,83. GUO Yandong,WANG Weihong,LIU Hua,et al.Research on the production influencing factors of shale gas multi-stage fractured horizontal well[J].Bulletin of Science and Technology,2018,34(4):72-78,83. [18] 林长城,丁文龙,王兴华,等.页岩储层地应力研究进展[J].科技通报,2018,34(7):1-8,20. LIN Changcheng,DING Wenlong,WANG Xinghua,et al.Research progress of geostress in shale reservoir[J].Bulletin of Science and Technology,2018,34(7):1-8,20. [19] 周芸,周福建,王信棚.表面活性剂酸性压裂液体系加砂压裂酸化模拟模型[J].科技通报, 2017,33(11):38-41. ZHOU Yun,ZHOU Fujian,WANG Xinpeng.Acidification simulation model of sand fracturing with surface active agent acid fracturing fluid system[J].Bulletin of Science and Technology,2017,33(11):38-41. [20] 陈志明,陈昊枢,廖新维,等.致密油藏压裂水平井缝网系统评价方法——以准噶尔盆地吉木萨尔地区为例[J].石油与天然气地质,2020,41(6):1288-1298. CHEN Zhiming,CHEN Haoshu,LIAO Xinwei,et al.Evaluation of fracture networks along fractured horizontal wells in tight oil reservoirs:a case study of Jimusar oilfield in the Junggar Basin[J].Oil & Gas Geology,2020,41(6):1288-1298. [21] 夏遵义,马海洋,房堃.渤海湾盆地沾化凹陷陆相页岩储层岩石力学特征及可压裂性研究[J].石油实验地质,2019,41(1):134-141. XIA Zunyi,MA Haiyang,FANG Kun.Rock mechanical properties and fracability of continental shale in Zhanhua Sag,Bohai Bay Basin[J].Petroleum Geology & Experiment,2019,41(1):134-141. [22] 王冲, 屈雪峰, 王永康, 等. 鄂尔多斯盆地致密油体积压裂水平井产量预测[J]. 西南石油大学学报(自然科学版), 2018, 40 (4): 123-131 . WANG Chong,QU Xuefeng,WANG Yongkang,et al.Production prediction for the volume-fracturing horizontal wells of a tight oil reservoir in the Ordos Basin [J].Journal of Southwest Petroleum University(Science & Technology Edition), 2018, 40 (4): 123-131. [23] 徐中一,方思冬,张彬,等.页岩气体积压裂水平井试井解释新模型[J].油气地质与采收率,2020,27(3):120-128. XU Zhongyi,FANG Sidong,ZHANG Bin,et al.A new well test model for horizontal wells by stimulated reservoir volume in shale gas reservoirs[J]. Petroleum Geology and Recovery Efficiency,2020,27(3):120-128. [24] 张子麟,陈勇,张全胜,等.致密砂砾岩压裂裂缝遇砾扩展模式的数值模拟研究[J].油气地质与采收率,2019,26(4):132-138. ZHANG Zilin,CHEN Yong,ZHANG Quansheng,et al.Numerical simulation on propagation mode of hydraulic fracture approaching gravels in tight glutenite[J].Petroleum Geology and Recovery Efficiency,2019,26(4):132-138. [25] 金成志, 何剑, 林庆祥, 等. 松辽盆地北部芳198-133 区块致密油地质工程一体化压裂实践[J]. 中国石油勘探, 2019, 24(2): 218-225. JIN Chengzhi, HE Jian, LIN Qingxiang, et al. Fracturing stimulation based on geology-engineering integration to tight oil reservoirs in Block Fang 198-133, northern Songliao Basin[J]. China Petroleum Exploration, 2019, 24(2): 218-225. |