职 务:油气消防省重点室副主任
职 称:教授
导师 资格:博导
所属 部门:油气储运工程研究所
学科 专业:油气储运工程
研究 方向:非常规原油降粘减阻、多相复杂流动保障、油气储运安全
联系 方式:13980987856;jjq@swpu.edu.cn
联系 地址:610500 成都市新都区新都大道85号金沙娱场城app7979
敬加强,男,1964年2月出生,博士(博士后),教授(博士生导师),四川省有突出贡献的优秀专家,油气消防四川省重点实验室副主任及学术委员会委员,教育部博士学位论文评审专家,国家自然科学基金委、国务院学位办与教育部、科技部、工信部等省部级以上项目和学位论文评审专家,《油气储运》《石油科学通报》《天然气与石油》等杂志编委、油气行业节能节水专标委委员,《Fuel》《JIEC》《石油学报》等20余种期刊审稿专家。长期从事“双一流”学科下油气储运工程专业的科研教学工作,每年为本科生授课1~2门、为硕士生与博士生各授课1门,累计指导本科毕业生200余人、硕士毕业生百余人、博士毕业生20人、博士后4人;负责“油气消防四川省重点实验室金沙娱场城app7979分室”与“复杂流动保障平台”的建设与管理,已形成非常规原油减阻节能、多相复杂管流保障、油气燃爆与储运安全等稳定研究方向,主持国家级与省部级项目20余项(其中,中俄国际合作与交流1项)、企业项目60余项;发表学术论文220余篇,其中SCI、EI收录百余篇,受邀开展专业相关理论与技术讲座或培训40余次、国内外学术交流30余次;主持出版科普读物1部、合著专著1部;授权美国发明专利1件、中国发明专利25件、实用新型专利30余件、软件著作权20余件;获省部级科技进步二等奖2项、三等奖6项。
(个人主页/sgy/szdw/jsml/jsml5/js/jjq.htm)
(1)教育经历
●1983.09-1987.07 西南石油学院,油气储运工程,学士
●1987.09-1990.07 西南石油学院,油气储运工程,硕士
●1996.09-1999.12 西南石油学院,石油与天然气工程,博士
(2)工作经历
●1990.07-2001.11 西南石油学院石油工程学院,助教、讲师
●2001.12-2005.03 西南石油学院石油工程学院,副教授(期间从事博士后工作并赴委内瑞拉考察)
●2005.04-至今 金沙娱场城app7979石油与天然气工程学院,教授;2009年博导、2014年省重室副主任、2020年省重室学术委员
●国家自然科学基金委,U19B2012,企业创新发展联合基金(中海油)重点合作项目,深水蜡晶与水合物多相混输管道固相沉积与安全输运机制,2020-2023,主持
●国家自然科学基金委中俄国际合作交流项目,51911530129,低温环境原油采输界面润滑与湍流减阻协同作用研究,2019-2020,主持
●国家自然科学基金委面上项目,51779212,深水原油采输管界面润滑流动改进机理研究,2018-2021,主持
●国家重大专项,2016ZX05025-004-005,海上稠油降粘减阻及输送关键技术研究,2016-2020,主持
●国家自然科学基金委青年基金项目,51606160,地形起伏管道油流携水机理研究,2017-2019,主研
●四川省科技厅科技计划项目,2019YJ0350,基于火灾烟雾扩散与火焰蔓延特征的抑火防爆理论与技术研究,2019-2021,主持
●四川省科技厅重点研发项目,2019YFS0075,复杂山地管道滑坡地质灾害监测预警技术研究及应用,2019-2021,主研
●国家自然科学基金,51074136,稠油流动边界层在水基泡沫作用下的阻力特性研究,2011-2013,主持
●高等学校博士点基金,20115121110004,稠油掺水流动粘度测定与压降预测研究,2012-2014,主持
●国家重大专项,2008ZX05026-004-04,海管内沥青质沉积预测及控制技术,2008-2010,主持
●国家重大专项,2008ZX05049-004-007HZ,超深层稠油降粘工艺技术配套,2008-2010,主持
●四川省科技计划项目,天然气场站燃爆规律及监控技术研究,2015-2017,主持
●金沙娱场城app7979中地共建项目,流体可视化环道实验装置研制,2007-2008,主持
●中石化西北油田分公司工程院,塔河井下稠油降粘流动模拟研究,2011-2012,主持
●中石化集团股份公司,新滩油田稠油乳化输送技术研究,2001-2003,主持
●中石油管道科技研究中心,降凝剂及其复配技术研究与应用,2005-2007,主持
●中石油管道科技研究中心,国外油气站场完整性管理技术研究,2007-2008,主持
●胜利油田胜利工程设计咨询公司,稠油掺水输送关键技术及水力计算方法研究,2007-2010,主持
●中海油渤海石油研究院,渤中25-1原油析蜡-流变性实验及评价,2005-2006,主持
●中石油管道科技研究中心,国内外管道标准对比分析与标准翻译,2009-1010,主持
●中海油上海分公司,春晓井口平台投产后海底湿气输送管道安全投运方案研究,2008-2009,主持
●中海油渤海石油研究院,BZ28-2S管输项目环道实验研究,2008-2009,主持
●中海油渤海石油研究院,BZ28-2S管输项目流变试验研究,2008-2009,主持
●中海油渤海采油工程研究院,渤中19-4油田原油环道试验研究,2009-2010,主持
●中石化西北油田分公司工程技术研究院,塔河稠油掺稀优化图版研究与应用,2010-2011,主持
●中石油华北油田分公司,阿赛线安全管理方案研究,2011-2012,主持
●中石油华北油田分公司,阿赛线安全运行方案研究,2011-2012,主持
●中石油西南分公司天研院,酸性气田低流速管线流体特征分析,2012,主持
●中石油新疆油田分公司勘探开发研究院,稠油井口掺采出水集输工艺研究,2009,主持
●中石油新疆油田分公司勘探开发研究院,红003稠油掺采出水集输工艺研究,2010,主持
●中石油新疆油田分公司工程院,2012小管径低输量输油管道安全运行技术研究,2012-2013,主持
●中石油新疆油田分公司勘探开发研究院,新疆沙漠油田含蜡原油集输经济安全运行方案研究,2013-2015,主持
●中石油西南CPECC,输气管道缓蚀剂预膜技术研究,2013-2016,主持
●中石油新疆油田分公司工程院,吉7井区稠油采输降粘减阻工艺研究,2013-2014,主持
●中石油四川销售公司,调和油质量评价与控制研究,2014-2015,主持
●中石油塔里木油田分公司,塔轮输油管线内腐蚀原因分析及对策研究,2014-2016,主持
●中石油新疆油田分公司工程院,新疆冷采稠油掺水集输的双管传热与温降规律研究,2013-2015,主持
●中石油新疆油田分公司油气储运公司,风城超稠油输送工艺研究,2009-2010,主持
●中海油研究总院项目,海底管道出砂监测原理样机加工测试,2014-2015,主持
●中国船级社项目,海上固定平台上部设备与系统完整性评估技术研究,2015-2016,主持
●四川省科技厅,油气消防四川省重点实验室建设,2014-2017,主持
●中石油新疆油田分公司工程院,吞吐开发方式稠油集输工艺技术界限研究,2017-2018,主持
●中石油新疆油田分公司工程院,新疆油田地面工程技术适应性分析,2017-2018,主持
●延长油田股份公司,杏子川采油厂油水井腐蚀机理与防治措施,2013-2017,主持
●中石油新疆油田分公司实验检测研究院,稠油注汽系统节能监测与评价方法,2016-2017,主持
●中石化西北油田分公司,顺北沙漠油气田开发地面工程技术研究与应用-顺北油气冷输工艺技术研究,2019-2020,主持
●海洋石油工程股份有限公司,稠油热采部分工程技术研究及应用课题-原油除砂技术服务,2020-2022,主持
●中石油新疆油田分公司工程院,高泉井区集输管道固相沉积规律及防治技术研究,2020-2021,主持
●中石化西北油田分公司,塔河高含水稠油乳化增稠机理及对策分析研究,2020-2021,主持
●中石化西北油田分公司,顺北二区高含硫化氢天然气脱水工艺研究,2020-2021,主持
●中石油新疆油田公司吉庆作业区,高凝点强乳化页岩油集输管流特性研究,2020-2021,主持
●中石化西北油田分公司,超深层稠油降粘举升技术与集成应用-塔河二、四区稠油乳化规律分析及治理对策测试与评价,2021-2022,主持
●中海油深圳分公司,深层低渗、稠油地面测试流程流动保障技术及工艺研究,2022-2023,主持
●中海石油(中国)有限公司北京研究中心,含蜡原油-气-水多相流动规律实验,2022-2023,主持
(1)学术论文
●Jing J Q,Guo Y Y,Karimov R,et al. Drag reduction related to boundary layer control in transportation of heavy crude oil by pipeline:A review[J]. Industrial & Engineering Chemistry Research,2023,62(37):14818-14834.(IF 4.2)
●Jing J Q,Zhuang L Q,Yang H,et al. Rheology properties of cyclopentane hydrate slurry in the presence of wax crystals[J]. Energy Sources Part A-Recovery Utilization And Environmental Effects,2023,45(3):7629-7647.(IF 2.9)
●Li W D,Jing J Q,Sun J,et al. Corrosion inhibitor distribution and injection cycle prediction in a high water-cut oil well:a numerical simulation study[J]. Sustainability,2023,15(7):6289.(IF 3.9)
●Zhang S J,Jing J Q,Luo M,et al. Experimental study on hydrocyclone desanding of high-viscosity oil[J]. Fuel,2023,341:127691.(IF 7.4)
●Li W D,Jing J Q,Sun J,et al. Investigation of the corrosion characteristics and corrosion inhibitor action on J55 steel in produced water[J]. Sustainability,2023,15(4):3355.(IF 3.9)
●Jing J Q,Zhuang L Q,Karimov R,et al. Investigation of natural gas hydrate formation and slurry viscosity in non-emulsifying oil systems[J]. Chemical Engineering Research & Design,2023,190:687-703.(IF 3.9)
●Yuan Y,Yin R,Jing J Q,et al. Establishment of a Reynolds average simulation method and study of a drag reduction mechanism for viscoelastic fluid turbulence[J]. Physics of Fluids,2023,35(1):1-18.(IF 4.6)
●Yu C,Han C J,Wang L,Jing J Q,et al. Numerical simulation of hydrate slurry flow behaviors with micron-sized sand in the transport pipe based on the population balance model[J]. Journal of Mechanical Science and Technology,2023,37(10):5159-5171.(IF 1.6)
●Yin X Y,Li J,Wen M,Dong X J,You X Y,Su M,Zeng P S,Jing J Q,et al. Study on the hydrodynamic performance and stability characteristics of oil-water annular flow through a 90° elbow pipe[J]. Sustainability,2023,15(8):6785.(IF 3.9)
●Yin R,Jing J Q,Yuan Y,et al. Preparation and performance evaluation of oil-tolerant and easy-wetting viscoelastic system for enhancing the stability of highly viscous oil-water lubricated flow[J]. Journal of Dispersion Science and Technology,2022,9:1-13.(IF 2.2)
●Zhang S J,Jing J Q,Qin M,et al. Experimental study and models of the settling of sand in heavy oil[J]. Journal of Petroleum Science and Engineering,2022,217:110930.(IF 4.4)
●Jing J Q,Yuan Y,Yin R,et al. Experimental research on synergistic drag reduction of cationic surfactant and nonionic polymer[J]. Petroleum Science and Technology,2023,41(1):45-63.(IF 1.5)
●Yu C,Wang L,Han C J,Jing J Q,et al. Aggregation behavior analysis of hydrate particles in the bend pipe based on the population balance model[J]. Journal of Mechanical Science and Technology,2022,36(7):3477-3486.(IF 1.6)
●Yin R,Jing J Q,Yuan Y,et al. Experimental analysis of flow characteristics and annular flow boundaries of highly viscous oil-water lubricated flow[J]. SPE Journal,2022,27(3):1831-1855.(IF 3.6)
●Tan J T,Hu H L,Sara V,Jing J Q,et al. Effects of drag-reducing polymers on the flow patterns,pressure gradients,and drag-reducing rates of horizontal oil-water flows[J]. International Journal of Multiphase Flow,2022,153:104136.(IF 3.8)
●Yuan Y,Jing J Q,Yin R,et al. Experimental research on cationic surfactants in the drag reduction of water injection pipeline[J]. SPE Production and Operations,2022,37(2):331-345.(IF 1.2)
●Sun J,Guo L J,Fu J Q,Jing J Q,et al. A new model for viscous oil-water eccentric core annular flow in horizontal pipes[J]. International Journal of Multiphase Flow,2022,147:103892.(IF 3.8)
●Sun J,Guo L J,Yin X Y,Jing J Q,et al. Investigation on drag reduction of aqueous foam for transporting thermally produced high viscosity oil[J]. Journal of Petroleum Science and Engineering,2022,210:110062.(IF 5.168)
●Jing J Q,Zhang S J,Qin M,et al. The effect of sand on the stability of heavy oil emulsions[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2022,635:127966.(IF 5.2)
●Shi W,Jing J Q,Wang Q,et al. Change in the cold flowability and wax deposition of crude oil by weak magnetic treatment[J]. Petroleum Science and Technology,2021,39(19-20):878-895.(IF 1.5)
●Xiao F,Luo M,Kuang S B,Zhou M M,Jing J Q,et al. Numerical investigation of elbow erosion in the conveying of dry and wet particles[J]. Powder Technology,2021,393:265-279.(IF 5.2)
●Jing J Q,Guo J,Li B,et al. Relationship between microstructure and corrosion behavior of high-grade pipeline steel in a low-temperature environment[J]. Journal of Iron and Steel Research(International),2021,28(8):1037-1046.(IF 2.5)
●Sun J,Guo L J,Jing J Q,et al. Investigation on laminar pipe flow of a non-Newtonian Carreau-Extended fluid[J]. Journal of Petroleum Science and Engineering,2021,205:108915. (IF 5.168)
●Jing J Q,Zhang S J,Qin M,et al. Numerical simulation study of offshore heavy oil desanding by hydrocyclones[J]. Separation and Purification Technology,2021,258(2):118051. (IF 7.8)
●Sun J,Guo L J,Jing J Q,et al. A comparison of numerical simulations with experimental and theoretical investigations of highly-viscous oil-aqueous foam horizontal flow[J]. Journal of Petroleum Science and Engineering,2021,201:108507.(IF 5.168)
●Jing J Q,Yin X Y,Mastobaev B N,et al. Experimental study on highly viscous oil-water annular flow in a horizontal pipe with 90°elbow[J]. International Journal of Multiphase Flow,2021,135:103499.(IF 3.8)
●Jing J Q,Yuan Y,Yin R,et al. Effects of oilfield injection water component on rheological characteristics of CTAC/NaSal aqueous solution[J]. Asia-Pac J Chem Eng,2020,16(2):e2612. (IF 1.7).
●Hu H L,Jing J Q,Vahaji S,et al. Investigation of the flow pattern transition behaviors of viscous oil-water flow in horizontal pipes[J]. Industrial & Engineering Chemistry Research,2020,59(47):20892-20902.(IF 4.1)
●Tan J T,Luo P Y,Vahaji S,Jing J Q,et al. Experimental investigation on phase inversion point and flow characteristics of heavy crude oil-water flow[J]. Applied Thermal Engineering,2020,180:115777.(IF 5.9)
●Zhang S J,Jiang H,Jing J Q,et al. Comprehensive comparison of enhanced recycle split vapour processes for ethane recovery[J]. Energy Reports,2020,6:1819-1837.(IF 5.6)
●Jing J Q,Du M J,Yin R,et al. Numerical study on two-phase flow characteristics of heavy oil-water ring transport boundary layer[J]. Journal of Petroleum Science and Engineering,2020,191:107173.(IF 4.5)
●Jing J Q,Yin R,Yuan Y,et al. Determination of the transportation limits of heavy crude oil using three combined methods of heating,water blending,and dilution[J]. ACS Omega,2020,5(17):9870-9884.(IF 4.0)
●Zhang S J,Jing J Q,Jiang H,et al. Advanced exergy analyses of modified ethane recovery processes with different refrigeration cycles[J]. Journal of Cleaner Production,2020,253:119982.(IF 11.0)
●Xiao F,Jing J Q,Kuang S B,et al. Capillary forces on wet particles with a liquid bridge transition from convex to concave[J]. Powder Technology,2020,363:59-73.(IF 5.0)
●Jing J Q,Wang S,Ling A J,et al. Rheological behavior of heavy crude oil and its emulsions[J]. Petroleum Science and Technology,2020,38(5):440-446.(IF 1.5)
●Tan J T,Jing J Q,Hu H L,et al. Extension of the Roscoe and Brinkman Viscosity Model for Unstable Oil-in-Water Dispersions[J]. Journal of Dispersion Science and Technology,2019,40(11):1618-1626.(IF 2.2)
●Jing J Q,Yuan Y,Du S J,et al. A CFD study of wet gas metering over-reading model under high pressure[J]. Flow Measurement & Instrumentation,2019,69:101608.(IF 2.3)
●Jing J Q,Shi W,Wang Q,et al. Viscosity-reduction mechanism of waxy crude oil in low-intensity magnetic field[J]. Energy Sources Part A-Recovery Utilization and Environmental Effects,2019,44(2):5080-5093.(IF 2.7)
●Jing J Q,Sun J,Huang H B,et al. Facilitating the transportation of highly viscous oil by aqueous foam injection[J]. Fuel,2019,251:763-778.(IF 7.0)
●Jing J Q,Yin R,Zhu G J,et al. Viscosity and contact angle prediction of low water-containing heavy crude oil diluted with light oil[J]. Journal of Petroleum Science and Engineering,2019,176:1121-1134.(IF 4.5)
●Jing J Q,Wang S,Xiao F,et al. Analysis of influence factors of start-up yield stress for heavy oil emulsions[J]. Petroleum Science and Technology,2019,37(11):1314-1322.(IF 1.5)
●Xiao F,Jing J Q,Han L,et al. Modelling and analysis of impact forces acting on elbow in gas-liquid slug flow[J]. Asia-Pacific Journal of Chemical Engineering,2019,14(2):e2284.(IF 1.7)
●Jiang H,Zhang S J,Jing J Q,et al. Thermodynamic and economic analysis of ethane recovery processes based on rich gas[J]. Applied Thermal Engineering,2019,148:105-119. (IF 5.9)
●Hu H L,Jiang H,Jing J Q,et al. Optimization and exergy analysis of natural gas liquid recovery processes for the maximization of plant profits[J]. Chemical Engineering & Technology,2019,42(1):182-195.(IF 1.9)
●Sun J,Jing J Q,Brauner N,et al. An oil-tolerant and salt-resistant aqueous foam system for heavy oil transportation[J]. Journal of Industrial and Engineering Chemistry,2018,68:99-108.(IF 5.6)
●Tan J T,Jing J Q,Hu H L,et al. Experimental study of the factors affecting the flow pattern transition in horizontal oil-water flow[J]. Experimental Thermal and Fluid Science,2018,98:534-545.(IF 3.5)
●Jiang H,Zhang S J,Jing J Q,et al. The improvement and analysis of the high-pressure propane recovery process[J]. Asia-Pacific Journal of Chemical Engineering,2018,13(5):e2246.(IF 1.7)
●Jing J Q,Xiao F,Yang L,et al. Measurements of velocity field and diameter distribution of particles in multiphase flow based on trajectory imaging[J]. Flow Measurement & Instrumentation,2018,59:103-113.(IF 2.3)
●Jing J Q,Xiao F,Yang L,et al. Experimental and simulation study of atomization concentration of corrosion inhibitor in a gas pipe[J]. Journal of Natural Gas Science & Engineering,2018,49:8-18.(IF 5.4)
●Jing J Q,Qi H Y,Jiang H Y,et al. Study on quantitative relationship between surface wettability and frictional coefficient of liquid flowing in a turbulent horizontal pipe[J]. China Petroleum Processing and Petrochemical Technology,2017,19(3):105-114.(IF 0.7)
●Sun J,Jing J Q,Jing P Y,et al. Preparation and performance evaluation of stable foamy heavy oil[J]. Petroleum Chemistry,2017,57(3):284-292.(IF 1.2)
●Sun N N,Jing J Q,Jiang H Y,et al. Effects of surfactants and alkalis on the stability of heavy-oil-in-water emulsions[J]. SPE Journal,2017,22(1):120-129.(IF 3.7)
●Jing J Q,Sun J,Zhang M,et al. Preparation and rheological properties of a stable aqueous foam system[J]. RSC Advances,2017,7(62):39258-39269.(IF 3.9)
●Sun J,Jing J Q,Wu C,et al. Pipeline transport of heavy crudes as stable foamy oil[J]. Journal of Industrial and Engineering Chemistry,2016,44:126-135.(IF 5.6)
●Sun J,Jing J Q,Jing P Y,et al. Experimental study on drag reduction of aqueous foam on heavy oil flow boundary layer in an upward vertical pipe[J]. Journal of Petroleum Science and Engineering,2016,146:409-417.(IF 4.5)
●Jing J Q,Tan J T,Huang M,et al. Addedwater heavy crude transport method improves efficiency[J]. Oil& Gas Journal,2016,114(4):70-74.(IF 0.1)
●Jing J Q,Sun J,Tan J T,et al. Investigation on flow patterns and pressure drops of highly viscous crude oil-water flows in a horizontal pipe[J]. Experimental Thermal and Fluid Science,2016,72:88-96.(IF 3.5)
●Jing J Q,Sun J,Zhou J,et al. Dynamic stability of heavy crude oil-in-water emulsions[J]. Journal of Dispersion Science and Technology,2016,37(7):980-990.(IF 2.2)
●Zhang P,Zheng S J,Jing J Q,et al. Surface erosion behavior of an intrusive probe in pipe flow[J]. Journal of Natural Gas Science and Engineering,2015,26:480-493.(IF 5.4)
●Jing J Q,Sun N N,An Y P,et al. Salt resistance of compound systems for amphoteric surfactant and HPAM[J]. ACTA Polymerica Sinica,2015,(1):88-96.(IF 1.3)
●Jing J Q,Duan N,Dai K M,et al. Investigation on drag characteristics of heavy oil flowing through horizontal pipe under the action of aqueous foam[J]. Journal of Petroleum Science and Engineering,2014,124:83-93.(IF 4.5)
●Jin W B,Jing J Q,Li Y,et al. Study on the inherent factors affecting the modification effect of EVA on waxy crude oils and the mechanism of pour point depression[J]. Journal of Dispersion Science and Technology,2014,35(10):1434-1441.(IF 2.2)
●Zhou M,Zhao J Z,Wang X,Jing J Q,et al. Synthesis and characterization of novel surfactants 1,2,3-tri(2-oxypropylsulfonate-3-alkylether-propoxy) propanes[J]. Journal of Surfactants and Detergents,2013,16(5):665-672.(IF 1.8)
●Chen C G,Jing J Q,Qiu Y J,et al. Characteristics and high viscosity analysis of heavy crudes from Tahe ultra-deep reservoirs[J]. Petroleum Science and Technology,2014,32(20):2480-2488.(IF 0.1)
●Jing J Q,Tang J T,Hu H L,et al. Rheological and emulsification behavior of xinjiang heavy oil and model oils[J]. The Open Fuels & Energy Science Journal,2016,9:1-10.(EI)
●郭雨莹,敬加强,黄婉妮,等.稠油管道水润滑减阻及压降预测模型修正[J].化工学报,2023,74(7):2898-2907.(EI)
●敬加强,陈勇,孙杰,等.天然气管道旁通清管研究进展[J].石油机械,2023,51(11):144-153.
●敬加强,郑天伦,杨航,等.气体水合物添加剂研究进展[J].天然气化工—C1化学与化工,2022,47(6):22-32.
●宋学华,陈玲,吴燕,杨航,罗金华,敬加强.高压含蜡油气集输管道蜡晶与水合物共存条件模拟分析[J].中国海上油气,2022,34(5):221-228.
●尹晓云,苏明,周鑫,张良,敬加强.水平管内黏稠油水环输送的稳定性[J].金沙娱场城app7979学报(自然科学版),2023,45(2):107-116.
●尹晓云,付林浩,李佳忆,程思杰,敬加强,等.稠油水环输送管道再启动压降特性分析[J].化工进展,2023,42(11):5669-5679.(EI)
●敬加强,程原招,张世坚,等. 含砂稠油卧式分离器数值模拟[J].石油机械,2022,50(3):57-64.
●敬加强,杨航,张帅,等.水合物生成诱导期研究进展[J].天然气化工—C1化学与化工,2022,46(6):24-32.
●敬加强,尹晓云,Mastobaev B N,等. T形管内雾状气液两相流相分离特性研究[J].石油机械,2021;49(9):122-128.
●敬加强,黄婉妮,宋学华,等.基于Fluent的井下油水分离和润滑过程中新型润滑元件设计分析[J]. 化工进展,2021,40(11):5929-5938.(EI)
●敬加强,张兴堂,王帅,等.停输海管内油水分布变化实验模拟及启动压力预测[J].水动力学研究与进展(A辑),2021,36(4):547-556.
●袁颖,敬加强,尹然.阳离子型表面活性剂与聚合物复配体系协同减阻作用[J].化工进展,2021,41(5):2593-2603.(EI)
●杜明俊,敬加强,张志贵,等.太阳能光热转换稠油热采关键技术[J].储能科学与技术,2020,9(S1):62-68.
●敬加强,尹晓云,Mastobaev B N,等.水平管内水环输送模拟稠油减阻特性[J].化工进展,2020,40(2):635-641.(EI)
●王帅,敬加强,宋学华,等.稠油乳状液屈服特性及环道启动压力预测[J].化工进展,2019,38(9):4020-4028.(EI)
●敬加强,蒋先勇,王春升,等.稠油-水混输对海管腐蚀行为影响因素研究[J].全面腐蚀控制,2019,33(6):6-13.
●蒋洪,张世坚,敬加强,等.常规及创新高压凝液回收流程对比[J].化工进展,2019,38(6):2581-2589.(EI)
●赵选烽,敬加强,王思汗,等.南阳含蜡原油混合输送的结蜡特性[J].石油化工,2019,48(1):65-70.
●敬加强,骆俊,张金钟.碱性介质温度对N80油管钢钝化膜的影响[J].腐蚀与防护,2018,39(9):694-697.
●敬加强,郭杰,刘清友,等.低温影响管线钢稳定性及焊接工艺的研究进展[J].钢铁,2018,53(8):8-14.
●檀家桐,敬加强,扈海莉,等.长输管道出站温度调整对燃料油耗量的影响研究[J].油气田地面工程,2018,37(6):41-43,48.
●敬加强,尹然,马孝亮,等.水平管稠油掺气减阻模拟实验[J].化工学报,2018,69(8):3398-3407. (EI)
●敬加强,刘黎,谢俊峰,等.输油管道腐蚀垢样中硫酸盐还原菌对Q235钢腐蚀行为的影响[J].腐蚀与防护,2018,39(1):6-10.
●敬加强,齐红媛,梁爱国,等.管道表面润湿性对层流流动阻力的影响[J].化工进展,2017,36(9):3203-3209.(EI)
●沈瞳瞳,敬加强,李蔚鹏,等.基于Fluent的水平管道稠油掺稀均质化流场模拟[J].科学技术与工程,2017,17(27):207-213.
●敬加强,孙娜娜,安云朋,等.两性表面活性剂与阴离子聚丙烯酰胺复配体系的抗盐性[J].高分子学报,2015(1):88-96.
●敬加强,孙杰,赵红艳,等.稠油流动边界层水基泡沫减阻模拟实验[J].化工学报,2014,65(11):4301-4308.(EI)
●敬加强,李业,代科敏,等.一种高稳定性水基泡沫体系的制备与性能评价[J].油田化学,2013,30(3):384-388.
●敬加强,肖飞,杨露,等.基于溶解速率和降粘率的稠油掺稀降粘实验[J].油田化学,2014,31(2):252-255.
●敬加强,周怡诺,段念,等.倾斜管中稠油流动边界层在水基泡沫作用下的减阻实验[J].科学通报,2015,60(7):681-688.
●敬加强,孙娜娜,安云朋,等.碱与乳化剂复合体系对稠油乳状液稳定性及流变性的影响[J].油田化学,2015,32(1):114-118.
●敬加强,杨梅,刘霞,等.基于热油管道结蜡不均匀性的蜡沉积厚度预测[J].油气田地面工程,2013,32(7):36-37.
●敬加强,杨蕾,蒋明佳,等.稠油掺水流动摩阻预测误差根源及对策[J].油气储运,2013,32(11):1151-1156.
●敬加强,代科敏,李业,等.水基泡沫降低稠油流动阻力的新思路[J].金沙娱场城app7979学报(自然科学版),2013,35(3):174-182.
●敬加强,代科敏,杨露,等.水基泡沫流变特性研究进展[J].金沙娱场城app7979学报(自然科学版),2013,35(1):173-178.
●敬加强,黄敏,杨莉,等.柴油稀释对原油流动性及析蜡过程的影响研究[J].金沙娱场城app7979学报(自然科学版),2009,31(2):146-150.
●敬加强,路平,杨莉,等.大庆原油加剂前后的蜡晶分形特性研究[J].金沙娱场城app7979学报(自然科学版),2008,30(2):123-126.
●敬加强,安云朋,孙娜娜,等.表面活性剂对部分水解聚丙烯酰胺溶液抗盐性的影响[J].高分子通报,2015,(5):61-68.
●安云朋,敬加强,刘雪健,等.稠油O/W型乳状液的低温稳定性[J].油田化学,2014,31(2):256-260,281.
●孙杰,敬加强,周怡诺,等.特稠油-水两相水平管流压降规律研究[J].中国科技论文,2015,10(11):1282-1285.
●田震,敬加强,靳文博,等.含蜡原油管道安全经济清管周期模型的建立与计算分析[J].中国海上油气,2015,27(2):120-126.
●靳文博,敬加强,田震,等.蜡沉积厚度随时间变化规律的模型研究[J].化工进展,2015,34(6):1544-1549.(EI)
●孙娜娜,敬加强,丁晔,等.无机盐阴阳离子对稠油水包油型乳状液稳定性的影响[J].化工进展,2015,34(8):3118-3123.(EI)
●邱伊婕,敬加强,孔祥伟,等.含水合物油包水管道输送体系压力波速研究[J].应用数学和力学,2014,35(10):1151-1162.
●李业,敬加强,代科敏,等.基于FLUENT的粘稠油垂直上升水环输送数值模拟[J].油气储运,2014,33(2):205-210.
●靳文博,敬加强,田震,等.基于最小二乘支持向量机的蜡沉积速率预测[J].化工进展,2014,33(10):2565-2569.(EI)
●明亮,敬加强,代科敏,等.塔河稠油掺稀粘度预测模型研究[J].油气储运,2013,32(3):263-269.
●伍鸿飞,敬加强,靳文博,等.原油族组成及碳数分布对其低温流动特性的影响[J].油气储运,2014,33(1):42-45.
●李业,敬加强,陈朝刚,等.塔河超深层中质油对稠油降粘的适应性[J].油气储运,2012,31(7):504-506.
●田茂昌,敬加强,万捷,等.稠油-水两相流乳化条件的实验模拟[J].油气储运,2012,31(4):250-253.
●杨露,敬加强,董正淼,等.新疆红山嘴油田红003稠油掺水流动特性[J].油气储运,2012,31(3):171-174.
●秦晓光,敬加强,骆畅,等.原油沥青质沉积测试分析及预测[J].油气田地面工程,2011,30(5):18-20.
●段林林,敬加强,牛洪彬,等.BZ28-2S混合稠油及其乳状液的特性[J].油气储运,2010,(5):331-333.
(2)学术报告与会议论文
●敬加强.深层稠油采输流固界面润滑减阻[R].2022国际石油石化技术会议与2022新能源及节能技术国际会议特邀报告及分会主持,线上,2022-10-12.
●敬加强.含蜡原油冷输理论与技术[R].北京:深水油气田蜡与水合物防控技术学术研讨会暨蜡沉积联合工业项目(2019-2022)成果发布会特邀报告,2022-09-06.
●敬加强.含蜡油粘温异常实质及流动改进[R].山东 青岛:第一届流变学青年学术沙龙特邀报告,2022-08-13.
●敬加强.海底管道伴热保温技术研究[R].双碳和新能源背景下防腐保温技术研讨会特邀报告,线上,2022-05-13.
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●Yin X Y,Jing J Q. Numerical simulation on filling process of drag reduction agent in natural gas pipeline[C]. Taiyuan:The 5th International Conference on Fluid Mechanics and Industrial Applications (FMIA 2021),June 26,2021.
●Sun J,Jing J Q. Study of non-Newtonian aqueous foam-Newtonian high-viscosity oil...
●非常规原油降粘减阻研究:主要涉及易凝高粘原油特别是高凝含蜡原油、特稠油与超稠油的高凝高粘实质及其流动改进机理与应用研究,高凝含蜡原油流动改进主要通过高聚物、热处理及机械剪切等途径来调整蜡晶结构及分散状态而实现,特稠油与超稠油流动改进主要通过掺水、掺稀、掺气、水环或泡沫环、乳化等手段来实现稠油的降粘减阻,该领域已取得特色鲜明的学术成果,并在陆上与海洋非常规原油采输(井筒举升及集输)中均有应用,社会经济效益显著。
●复杂多相流动保障研究:依托具有独立知识产权的多功能流体环道装置,主要研究气或液单相流、气气或液液掺混流、油水/油气/气水/液固(砂)/气固(砂)等两相流、泡排采出物/油气水/油气水固多相流、粘油泡沫/水膜润滑流等水平管、垂直管、倾斜管及大落差管流特性、蜡与水合物等固相沉积及其耦合沉积、油气管道停输再启动行为,为油气采输工艺合理设计与安全经济运行提供基础数据,该领域也取得了丰硕的学术成果及成果转化。
●油气储运工程安全研究:依托四川省威特龙消防集团、金沙娱场城app7979、中国石油工程设计公司西南CPE共建的油气消防四川省重点实验室,主要研究油气采出流体在储存与运输过程中的腐蚀性、扩散性、燃爆性及其主动防护等方面的应用基础研究与成果转化。
“复杂流动保障研究”平台由1位教授、1位研究员、2位副教授、多位讲师和硕博研究生组成,在非常规原油降粘减阻、复杂多相流动保障、油气储运工程安全等领域已形成稳定的研究方向,在油气集输规划与运行优化、油气采输管润滑减阻、复杂油气多相流控制、油气系统腐蚀与完整性管理、油气储运原理样机研发等方面具有鲜明的研究特色。团队承担国家自然基金、国家油气重大专项等国家级项目11项、省部级项目20余项,油气田合作项目130余项,研究成果获省部级奖励7项;出版本科及研究生教材、专著等6部,发表学术论文300余篇,SCI、EI收录150余篇;授权发明专利60余项、实用新型专利50余项、软件著作权30余项。