职 称:教授
导师 资格:博导
所属 部门:采油所
学科 专业:油气田开发工程
研究 方向:增产改造
联系 方式:Wangshb07@163.com
联系 地址:610500 版权所有 红宝石官方网站hbs123 - 红宝石最新线路手机版红宝石官方网站hbs123国家重点实验室A307
四川省学术学科带头人后备人选,入选四川省杰出青年学术技术带头人资助计划,“油气藏地质及开发国家重点实验室”固定研究人员,教育部创新团队发展计划“致密油气藏增产改造理论与技术”(培育)学术方向带头人;四川省科技创新研究团队专项计划“储层增产改造”学术方向带头人。在国内外期刊发表论文35篇,其中SCI收录22篇,获国家发明专利授权23项;获得省部级以上科技研究奖励5项。主持完成国家油气重大专项4项;主持和参加完成部省级科研项目和油田协作重大项目十余项,多项研究成果在油田推广应用。
●2000.09-2003.07 南开大学,化学,硕士
●2004.09-2007.07 清华大学,化学,博士
●2007.07-2009.12 红宝石官方网站hbs123,讲师
●2016.03-2017.03 美国密苏里科技大学访问学者
●2010.01-2017.12 红宝石官方网站hbs123,副研究员
●2018.01-至今 红宝石官方网站hbs123,教授
●功能性水溶压裂液稠化剂合成配方优化,2020/09-2021/06,主持
●苏里格气田致密砂岩储层改造伤害机理及治理对策研究与试验,2020/06-2021/12,主持
●相酸体系缓速机理与性能研究,2020/06-2021/06,主持
●国家油气重大专项,解吸附剂研制及低伤害压裂液技术研究,2016/01-2020/06,主持
●国家油气重大专项,滑溜水低吸附压裂液和纳米杂化高温压裂液,2016/01-2020/12,主持
●西北超深井高效钻完井工艺技术,顺北定容储层强堵强压材料测试,2018/12-2019/09,主持
●四川省杰出青年学术技术带头人资助计划,2016/01-2018/12
●四川省科技支撑计划,高矿化度可回收利用滑溜水压裂液体系研究及现场试验,2015/01-2017/12,主持
(1)文章
●Liu J W,Wang S B,He L,et al. Preparation and properties of nano-silica hybrid hydrophobic associated polyacrylamide for polymer flooding[J]. Journal of Petroleum Science and Engineering,2022,208(PB).
●Zhao F,Wang S B,Guo J C. Experimental and molecular dynamics simulation study on the effects of the carbon chain length of gemini surfactants on the inhibition of the acid-rock reaction rate[J]. Langmuir:the ACS journal of surfaces and colloids,2021,37(17).
●Shen X,Wang S B,Guo J C,et al. Effect of carbon chain lengths of cationic surfactant on inhibition rate of acid-rock reactioncc[J]. Journal of Petroleum Science and Engineering,2021,196.
●Liu J W,Wang S B,Wang C,et al. Influence of nanomaterial morphology of guar-gum fracturing fluid,physical and mechanical properties[J]. Carbohydrate polymers,2020,115915.
●Zhao F,Wang S B,Shen X,et al. Study on mechanism of Gemini surfactant inhibiting acid rock reaction rate[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2019,578.
●Li Y,Wang S B,Guo J C,et al. Reducing adsorption of hydroxypropyl guar gum on sandstone by silicon nanoparticles[J]. Carbohydrate Polymers,2019,219.
●Chen R Y,Wang S B,Shen X,et al. Effect of Ca2+ on viscosity and microstructure of water-soluble triblock terpolymer used as thicker in the hydraulic fracturing[J]. Journal of Applied Polymer Science,2019,136(20):47539.
●Guo J C,Ren J C,Wang S B,et al. Comprehensive study of fracture flow characteristic and feasibility of hybrid volume stimulation technique in tight fractured carbonate gas reservoir[J]. Journal of Petroleum Science and Engineering,2019,174.
●Li Y,Guo J C, Wang S B. The damage mechanisms of fracturing fluid on production in tight gas reservoirs[J]. Energy Procedia,2019,158.
●Wang S B,Chen F H,Guo J C,et al. Adsorption damage of hydroxypropyl guar gum to porous media composed of quartz[J]. Journal of Petroleum Science and Engineering,2019,182(C).
●Li Y,Wang S B,Guo J C,et al. Reduced adsorption of polyacrylamide‐based fracturing fluid on shale rock using urea[J]. Energy Science & Engineering,2018,6(6).
●Wang S,Zhang D,Guo J,et al. Experiment and analysis of the reaction kinetics of temperature control viscosity acids with limestone[J].Journal of Petroleum ence & Engineering,2018:S092041051830127X.
●Aliu AO,Guo J C,Wang S B. Quantifying regain conductivity in proppant packs using broken Na-CMC fracture fluid[J]. Journal of Natural Gas Science and Engineering,2017:S1875510017302962.
●Wang S B,Li G,Li Y,et al. Adsorption of new hydrophobic polyacrylamide on the calcite surface[J]. Journal of Applied Polymer Science,2017,134(38):4.
●Aliu AO,Guo J C,Wang S B. Hydraulic fracture fluid for gas reservoirs in petroleum engineering applications using sodium carboxy methyl cellulose as gelling agent[J]. Journal of Natural Gas ence and Engineering,2016:491-500.
●Wang S B,Tang H B,Guo J C,et al. Effect of pH on the rheological properties of borate crosslinked hydroxypropyl guar gum hydrogel and hydroxypropyl guar gum[J]. Carbohydrate Polymers,2016,147:455-463.
●Wang S,Yang R,Guo J,et al. Phenothiazine organic dyes with the cone-shaped structural:Broad photoresponse and limitations on short-circuit photocurrent density in dye-sensitized solar cells[J]. Synthetic Metals,2016,215:184-193.
●Wang S B,He L,Guo J C,et al. Intrinsic viscosity and rheological properties of natural and substituted guar gums in seawater[J]. International Journal of Biological Macromolecule,2015,76.
●Wang S B,Zhang Y Y,Guo J C,et al. A study of relation between suspension behavior and microstructure and viscoelastic property of guar gum fracturing fluid[J]. Journal of Petroleum Science and Engineering,2014,124:32-435.
●Wang S B,Wang H,Guo J C,et al. Influence of the terminal electron donor in DeDepe Aphenothiazine dyes for dye-sensitized solar cells[J]. Dyes & Pigments,2014,109:96-104.
●Wang S B,Guo J C,He L,et al. Influence of thiophene and benzene unit in triphenylamine dyes on the performance of dye-sensitized solar cells[J]. Synthetic Metals,2013,168(Complete):1-8.
●Wang S B,Guo J C,Yan D,et al. Efficient triphenylamine photosensitizers with alkoxy-or fluorine-substituted phenylene spacer for dye-sensitized solar cells[J]. Journal of Materials Science,2012,47(4):1843-1851.
●易辉永,王世彬,李帅帅,等.纤维素纳米晶杂化压裂液的流变性能[J].油田化学,2021,38(02):230-234.DOI:10.19346/j.cnki.1000-4092.2021.02.007.
●郭建春,李杨,王世彬.氢键抑制方法减少瓜尔胶压裂液对砂岩储层的吸附伤害[J].天然气工业,2019,39(07):57-62.
●李杨,郭建春,王世彬,等.耐高温压裂液研究现状与发展趋势[J].现代化工,2019,39(S1):95-98.DOI:10.16606/j.cnki.issn0253-4320.2019.S.020.
●申鑫,王世彬,张永春,等.阳离子表面活性剂的碳链长度对缓速性能影响[J].油田化学,2018,35(4):643-647+664.DOI:10.19346/j.cnki.1000-4092.2018.04.015.
●李杨,郭建春,王世彬,等.低伤害压裂液研究现状及发展趋势[J].现代化工,2018,38(9):20-22+24.DOI:10.16606/j.cnki.issn0253-4320.2018.09.005.
●王川,王世彬,郭建春.纳米陶粉对胍胶压裂液性能的影响[J].油田化学,2018,35(01):31-35. DOI:10.19346/j.cnki.1000-4092.2018.01.006.
●郭建春,李杨,王世彬.滑溜水在页岩储集层的吸附伤害及控制措施[J].石油勘探与开发,2018,45(2):320-325.
●王坤杰,王世彬,郭建春.准噶尔盆地储集层各向异性特征及破裂压力预测研究[J].钻采工艺,2017,40(4):32-35+3.
●唐洪彪,王世彬,郭建春. pH值对羟丙基胍胶压裂液性能的影响[J].油田化学,2016,33(2):4.
●王世彬,王浩儒,郭建春,等.砂岩储层酸化自转向酸研究与应用[J].油田化学,2015,32(4):490-493. DOI:10.19346/j.cnki.1000-4092.2015.04.004.
●何乐,王世彬,郭建春,等.高矿化度水基压裂液技术研究进展[J].油田化学,2015,32(4):621-627.DOI:10.19346/j.cnki.1000-4092.2015.04.032.
●庄园,王世彬,郭建春.提高均质致密碳酸盐岩储层酸蚀裂缝导流能力效果研究[J].科学技术与工程,2014,14(20):35-38.
●王浩儒,王世彬,郭建春.自转向土酸在青海油田储层改造中的应用[J].科学技术与工程,2014,14(15):177-180.
●张德政,王世彬,郭建春.考虑幂律特性的胶凝酸酸岩反应动力学研究[J].石油天然气学报,2014,36(11):192-196+11.
●王恒,王世彬,郭建春,等.酸压滤失体积表征与计算方法研究[J].断块油气田,2014,21(2):266-268.
●王世彬,张艺耀,郭建春,等.酶降解制备小分子瓜尔胶[J].油田化学,2014,31(2):195-198.DOI:10.19346/j.cnki.1000-4092.2014.02.009.
●何乐,王世彬,郭建春,等.海水中瓜尔胶溶胀性能研究[J].油田化学,2014,31(2):207-210.DOI:10.19346/j.cnki.1000-4092.2014.02.012.
●蒋淮宇,王世彬,郭建春,等.提高低温条件下过硫酸铵分解速率的方法[J].钻井液与完井液,2012,29(1):2.
(2)专利
●王世彬,胡鹏,石磊,等.一种适用于二次压裂的水溶性暂堵剂及其制备方法:110283578B[P].2021-10-01.
●管保山,王世彬,许可,等.一种耐高温碳纳米管杂化压裂液及其制备方法:113265234A[P].2021-08-17.
●管保山,王世彬,许可,等.一种改性氧化石墨烯杂化瓜尔胶压裂液体系及其制备方法:113265235A[P].2021-08-17.
●王世彬,刘成城,石朋,等.一种固体缓速酸的注入方法:111364964B[P].2020-09-25.
●王世彬,高杨,徐兵威,等.一体化压裂施工中稠化剂的添加方法:111287719A[P].2020-06-16.
●王世彬,王志,石朋,等.一种用于连续施工的稠化剂乳液的制备方法及其使用方法:111234797A[P].2020-06-05.
●王世彬,刘成城,易辉永,等.一种纤维素纳米晶杂化的压裂液及其配制方法:111205848A[P].2020-05-29.
●王世彬,李杨,郭建春,等.一种低吸附伤害滑溜水体系:108865105B[P].2019-06-14.
●王世彬,赵峰,郭建春,等.用于低渗透碳酸盐岩储层酸化的缓速酸体系及其制备方法:109554174A[P].2019-04-02.
●王世彬,石磊,李杨,等.一种纳米粒子复合高温瓜胶压裂液:109097019A[P].2018-12-28.
●李杨,郭建春,王世彬,等.一种致密砂岩储层胍胶压裂液吸附伤害实验评价装置:207703850U[P].2018-08-07.
●王世彬,易辉永,李杨,等.一种降低胍胶压裂液在砂岩储层伤害的解除剂:108084984A[P].2018-05-29.
●王川,王世彬.一种具有液体预混合功能的粘附系数测定仪:207007644U[P].2018-02-13.
●王世彬,李杨,郭建春,等.一种控制水力压裂裂缝延伸下端高度的导向剂:107629781A[P]. 2018-01-26.
●王世彬,赵峰,郭建春,等.一种控制水力裂缝延伸高度的方法:107503725A[P].2017-12-22.
●王世彬,陈付虎,郭建春,等.一种碳纳米管掺杂的压裂液体系:106433603A[P].2017-02-22.
●王世彬,郭建春,李泰良,等.一种解除钻井液加重剂堵塞的清除液:104073229A[P].2014-10-01.
●王世彬,郭建春,赖杰,等.一种适用于高矿化度水压裂液的交联剂:103497753A[P].2014-01-08.
●王世彬,郭建春,张艺耀,等.一种适用于140-180℃地层酸化的缓蚀剂:102827596A[P].2012-12-19.
●王世彬,郭建春,邓燕.一种用于压裂酸化作业的快速破乳剂及其制备方法:102250608A[P].2011-11-23.
(3)获奖
●全国“互联网+”学生创新创业大赛,铜奖,2020
●四川省“互联网+”学生创新创业大赛,金奖,2019
●四川省科技进步一等奖,致密气藏水平井多裂缝渗流与精细分段压裂关键技术及推广应用,2014
●中国石油和化学工业联合会技术发明一等奖,高温深层油气藏支撑剂高效铺置压裂技术与应用,2013
●中国专利优秀奖,适用于160℃-200℃地层加砂压裂的交联剂,2012
研究方向为油气田增产改造工作液与工艺。针对增产改造过程入井液与岩石作用问题,研究新型的入井流体,优化入井流体的性能,为解决增产改造中的各种难题提出针对性强、创造性强和应用效果显著的入井液体系和配套工艺技术。
研究团队为压裂酸化创新团队,是红宝石官方网站hbs123压裂酸化方向的核心研究力量,目前拥有骨干研究人员8人(全部拥有博士学位)。本团队始终站在学科发展的前沿,立足于为我国复杂油气藏的储层改造提供全面系统的理论和技术支持,取得了一系列创新性研究成果,在我国环渤海湾盆地、塔里木盆地、四川盆地、冀中凹陷和鄂尔多斯盆地等油气区块得到推广应用,成果应用解决了国内复杂油气藏改造所遇到的一系列关键技术难题,应用效果良好,产生经济效应显著。