職 稱:副研究員
導師 資格:碩導
所屬 部門:采油所
學科 專業:油氣田開發工程
研究 方向:油氣田增產理論
聯系 方式:13880152374;[email protected]
聯系 地址:610500 四川省成都市新都區新都大道85號西南石油大學
楊小江,男,1988年生,博士,講師,主要從事油氣田增產改造工作液體系的研發,包括傳統聚合物壓裂液體系、高性能清潔壓裂液體系、加重壓裂液體系、功能性酸化液體系等,致力于將最新理論、方法和技術應用于油氣田增產改造工作液新材料的研發當中。近年來主要圍繞油氣田增產改造工作液體系功能性添加劑的研究,在稠化劑產品及其配套添加劑方面具有較深刻的認識。2016年8月赴南非開普敦大學交流訪問,2017年獲國家留學基金委資助,赴加拿大卡爾加里大學公派留學一年。發表學術論文67余篇,其中SCI收錄62篇,擔任《FUEL》《Energy & Fuel》《Journal of Natural Gas Science and Engineering》《Journal of Dispersion Science and Technology》《Journal of Molecular Liquids》《Energy Sources,Part A:Recovery,Utilization,and Environmental Effects》《Petroleum》《Petroleum Science》《ACS Omega》等期刊的審稿專家。
●2007.09-2011.06 西安石油大學,信息與計算科學,學士
●2011.09-2014.06 西安石油大學,油氣田開發工程,碩士
●2016.08-2016.09 南非開普敦大學,訪問
●2015.09-2018.06 西南石油大學,油氣田開發工程,博士
●2017.09-2018.09 加拿大University of Calgary,化學與石油工程系,博士聯合培養
●2018.09-至今 西南石油大學石油與天然氣工程學院,任教
●國家自然科學基金青年項目,52104035,復雜介質中pH刺激響應型蠕蟲狀膠束體系構建及其機理研究,2022.01-2012.12,主持
●中國博士后科學基金面上項目一等資助,216447,基于相分離的可回收清潔壓裂液稠化劑及其機理研究,2019.06-2021.06,主持
●四川省區域創新合作項目,2020YFQ0031,陸相低滲透油藏攜砂擠液儲層改造技術,2020.01-2022.12,主持
●中石化東北油氣分公司,34500000-18-ZC0607-0002,松南火山巖氣藏水平井清潔轉向酸液體系研發,2018.11-2019.08,主持
●中石油渤海鉆探工程公司井下作業分公司,BHZT-JXZYGS-2020-JS-4,吉蘭泰油田吉華2斷塊砂礫巖油藏儲層保護機增產措施技術研究,2020.03-2021.03,主持
●中國石油化工股份有限公司西北油田分公司,3400007-19-ZC0607-0044縫洞型油藏選擇性堵水技術優化及應用-縫洞型油藏低效堵水原因分析及配套堵劑測試評價,2019.07-2020.07,主持
●中國石油集團渤海鉆探工程有限公司井下作業分公司,2021510102002290,多元有機酸酸液體系合作技術開發,2021.10-2022.10,主持
(1)發表學術論文(第一/通訊作者)
●Yang X J,Mao J C,Zhang H,et al. Copper-catalyzed aerobic oxidation reaction of benzyl alcohol in water under base-free condition[J]. Chinese Journal of Organic Chemistry,2018,38(10):2780-2783.
●楊小江,毛金成,張恒,等.無堿條件下銅催化的芐醇在水中的氧化反應(英文)[J].有機化學,2018(10):2780-2788.
●Yang X J,Mao J C,Zhang Z Y,et al. Rheology of quaternary ammonium gemini surfactant solutions:effects of surfactant concentration and counterions[J]. Journal of Surfactants and Detergents,2018,21(4):467-474.
●Yang X J,Mao J C,Zhang H,et al. Reutilization of thickener from fracturing flowback fluid based on Gemini cationic surfactant[J]. Fuel,2019,Vol.235:670-676.
●Yang X J,Mao J C,Chen Z X,et al. Clean fracturing fluids for tight reservoirs:opportunities with viscoelastic surfactant[J]. Energy Sources Part A-Recovery Utilization and Environmental Effects,2019,41(12):1446-1459.
●Yang X J,Mao J C,Zhang W L,et al. Tertiary cross-linked and weighted fracturing fluid enables fracture stimulations in ultra high pressure and temperature reservoir[J]. Fuel,2020,Vol.268:117222.
●Yang X J,Mao J H,Mao J C,et al. The role of KCl in cationic Gemini viscoelastic surfactant based clean fracturing fluids[J]. Colloids Surf. A Physicochem. Eng. Asp.,2020,606:125510.
●Zhang Q,Mao J C,Yang X J,et al. Synthesis of a hydrophobic association polymer with an inner salt structure for fracture fluid with ultra-high-salinity water[J]. Colloids and Surfaces A-Physicochemical and Engineering Aspects,2022,636:128062.
●Mao J C,Yang X J,Chen Y N,et al. Viscosity reduction mechanism in high temperature of a Gemini viscoelastic surfactant (VES) fracturing fluid and effect of counter-ion salt (KCl) on its heat resistance[J]. Journal of Petroleum Science and Engineering,2018,164:189-195.
●毛金成,楊小江,宋志峰,等.耐高溫清潔壓裂液體系HT-160的研制及性能評價[J].石油鉆探技術,2017(6):105-109.
●Mao J C,Yang X J,Wang D L,et al. A novel gemini viscoelastic surfactant (VES) for fracturing fluids with good temperature stability[J]. RSC Advances,2016,6(91):88426-88432.
●Mao J C,Yang X J,Wang D L,et al. Pd-catalyzed oxidative olefination of arenes with olefins via C-H activation:Retention of the leaving group[J]. Russian Journal of Applied Chemistry,2015,88(12):2050-2055.
●Mao J C,Yang X J,Wang D L,et al. Optimization of effective sulfur solvents for sour gas reservoir[J]. Journal of Natural Gas Science and Engineering,2016,36:463-471.
●Mao J C,Yang X J,Yan H,et al. Effective Synthesis of Benzyl 3-Phenylpropiolates Via Copper(I)-Catalyzed Esterification of Alkynoic Acids with Benzyl Halides Under Ligand-Free Conditions[J]. Catalysis Letters,2016,146(5):886-892.
●Mao J C,Wang D L,Yang X J,et al. Application and optimization:Non-aqueous fracturing fluid from phosphate ester synthesized with single alcohol[J]. Journal of Petroleum Science and Engineering,2016,147:356-360.
●Mao J C,Liu J W,Wang H B,Yang X J,et al. Novel terpolymers as viscosity reducing agent for Tahe super heavy oil[J]. RSC Advances,2017,7(31):19257-19261.
●Zhang W L,Mao J C,Yang X J,et al. Study of a novel gemini viscoelastic surfactant with high performance in clean fracturing fluid application[J]. Polymers,2018,10(11):1215.
●Mao J C,Zhang C,Yang X J,et al. Investigation on problems of wastewater from hydraulic fracturing and their solutions[J]. Water Air Soil Pollut.,2018,229(8):246.
●Mao J C,Wang D L,Yang X J,et al. Experimental study on high temperature resistance aluminum-crosslinked non-aqueous fracturing fluids[J]. Journal of Molecular Liquids,2018,258:202-210.
●Mao J C,Kang Z,Yang X J,et al. Synthesis and performance evaluation of a nanocomposite pour-point depressant and viscosity reducer for high-pour-point heavy oil[J]. Energy & Fuels,2020,34(7):7965-7973.
●Zhang W L,Mao J C,Yang X J,et al. Effect of propylene glycol substituted group on salt tolerance of a cationic viscoelastic surfactant and its application for brine-based clean fracturing fluid[J]. Colloids Surf. A Physicochem. Eng. Asp.,2020,584:124043.
●Mao J C,Wang C,Yang X J,et al. Self-diverting acid system with retarding function for heterogeneous carbonate reservoirs stimulation[J]. J. Surfactants Deterg.,2020,23(4):831-839.
●Zhang W L,Mao J C,Yang X J,et al. Development of a sulfonic gemini zwitterionic viscoelastic surfactant with high salt tolerance for seawater-based clean fracturing fluid[J]. Chemical Engineering Science,2019,207:688-701.
●Zhang W L,Mao J C,Yang X J,et al. Development of a Stimuli-Responsive Gemini Zwitterionic Viscoelastic Surfactant for Self-Diverting Acid[J]. J. Surfactants Deterg.,2019,22(3):535-547.
●Mao J C,Wang D L,Yang X J,et al. Exploration of low adsorption surfactants for reservoir stimulation[J]. Journal of The Taiwan Institute of Chemical Engineers,2019,95:424-431.
●Zhang Z Y,Mao J C,Yang X J,et al. Advances in waterless fracturing technologies for unconventional reservoirs[J]. Energy Sources Part A-Recovery Utilization and Environmental Effects,2019,41(2):237-251.
●毛金成,韓滌非,楊小江,等.特種聚酰亞胺作為油田管材涂層的性能評價[J].科學技術與工程,2019(28):129-135.
●Huang Z G,Mao J C,Cun M,Yang X J,et al. Polyhydroxy cationic viscoelastic surfactant for clean fracturing fluids:Study on the salt tolerance and the effect of salt on the high temperature stability of wormlike micelles[J]. Journal of Molecular Liquids,2022,366:120354.
●Lin C,Mao J H,Mao J C,Yang X J,et al. Experimental Study on the Strength and Failure Mechanism of Hollow Hot Dry Rocks Under Brazilian Splitting Tests[J]. Arabian Journal for Science and Engineering,2022(9):11125-11134.
●Mao J C,Xue J X,Zhang H,Yang X J,et al. Investigation of a hydrophobically associating polymer’s temperature and salt resistance for fracturing fluid thickener[J]. Colloid and Polymer Science,2022(5):1-2.
●Mao J C,Huang Z G,Cun M,Yang X J,et al. Effect of spacer hydroxyl number on the performance of Gemini cationic viscoelastic surfactant for fracturing fluids[J]. Journal Of Molecular Liquids,2022,46:117889.
●Mao J C,Liao Z J,Jiang J X,Yang X J,et al. One practical CaCl2-weighted fracturing fluid for high-temperature and high-pressure reservoir[J]. Petroleum Science and Technology,2022,40:23.
●Zhang W L,Mao J C,Jia Z F,Yang X J,et al. Design of a salt-tolerant Gemini viscoelastic surfactant and the study of construction of wormlike micelle structure in high-salinity aqueous environment[J]. Colloids and Surfaces A-Physicochemical and Engineering Aspects,2021,631:127653.
●Xu T,Mao J C,Zhang Y,Yang X J,et al. Experimental study on high-performers quaternary copolymer based on host-guest effect[J]. Polymers,2021,13(17):2972.
●Tian J Z,Mao J C,Zhang W L,Yang X J,et al. Salinity and heat-tolerant VES (Viscoelastic Surfactant) clean fracturing fluids strengthened by a hydrophobic copolymer with extremely low damage[J]. Chemistryselect,2021,6(9):2126-2143.
●Xu T,Mao J C,Zhang Y,Yang X J,et al. Application of gemini viscoelastic surfactant with high salt in brine-based fracturing fluid[J]. Colloids and Surfaces A-Physicochemical and Engineering Aspects,2021,611:125838.
●Zhang H,Mao J C,Zhao J Z,Yang X J,et al. The impact of dissymmetry on the aggregation properties of heterogemini surfactants[J]. Colloids Surf. A Physicochem. Eng. Asp.,2020,585:124165.
●Tian J Z,Mao J C,Zhang W L,Yang X J,et al. Application of a zwitterionic hydrophobic associating polymer with high salt and heat tolerance in brine-based fracturing fluid[J] .POLYMERS,2019,11(12):2005.
●Mao J C,Tian J Z,Zhang W L,Yang X J,et al. Effects of a counter-ion salt (potassium chloride) on gemini cationic surfactants with different spacer lengths[J]. Colloids And Surfaces A-Physicochemical And Engineering Aspects,2019,578:123619.
●Zhang Z Y,Mao J C,Yang B,Yang X J,et al. Experimental evaluation of a novel modification of anionic guar gum with maleic anhydride for fracturing fluid[J]. Rheologica Acta,2019,58(3-4):173-181.
●Zhang Y,Mao J C,Zhao J Z,Yang X J,et al. Preparation of a hydrophobic-associating polymer with ultra-high salt resistance using synergistic effect[J]. Polymers,2019,11(4):626.
●Zhang Y,Mao J C,Zhao J Z,Yang X J,et al. Preparation of a novel ultra-high temperature low-damage fracturing fluid system using dynamic crosslinking strategy[J]. Chemical Engineering Journal,2018,354:913-921.
●Zhao J Z,Fan J M,Mao J C,Yang X J,et al. High performance clean fracturing fluid using a new tri-cationic surfactant[J]. POLYMERS,2018,10(5):535.
●Mao J C,Li R,He Y,Yang X J,et al. Palladium-catalyzed synthesis of diarylbenzenes from coupling reactions between equal amount of diiodoarenes and arylboronic acids[J]. Russian Journal of Applied Chemistry,2016,89(4):663-669.
(2)授權專利
●楊小江,毛金成,張陽,等.一種高密度水基清潔(VES)壓裂液及其稠化劑的制備:201910054916.8[P]. 2021-01-12.
●楊小江,毛金成,張恒.可回收清潔壓裂液稠化劑及其制備方法、回收方法以及耐高溫清潔壓裂液:201810942253.9[P]. 2020-07-28.
●Yang X J,Mao J C,Zhang H. Recyclable Clean Fracturing Fluid Thickener,Preparation Method and Recovery Method Thereof,and High-Temperature Resistant Clean Fracturing Fluid:US10894761 [P]. 2021-01-19.
●Yang X J,Han D F,Mao J C,et al. Emulsifer With High Temperature Resistance,Low Viscosity and Low Corrosiveness,and Emulsified Acid System Comprising Same:US 11377589[P]. 2022-07-05.
●Mao J C,Zhang Y,Zhao J Z,Yang X J,et al. Self-Healing,Low-Damage and Ultra-High Temperature-Resistant Fracturing Fluid:US10633576[P]. 2020-04-28.
●Mao J C,Fan J M,Zhao J Z,Yang X J. Tri-cationic viscoelastic surfactant,preparation method and application thereof and clean fracturing fluid:US10870790[P]. 2020-12-22.
●毛金成,楊小江,張恒,等.一種雙子兩性黏彈性表面活性劑及其制備方法和以其為稠化劑的清潔壓裂液:201610578298.3[P]. 2018-08-24.
●毛金成,楊小江,李勇明,等.一種新型聚醚胺類的高效硫溶劑及其制備方法:201510557711.3[P]. 2018-04-20.
●毛金成,楊小江,李勇明,等.一種常溫硫溶劑及其制備方法:201510556480.4[P] 2018-06-29.
●毛金成,楊小江,李勇明,等.一種溶硫劑及其制備方法:201510557608.9[P]. 2018-07-06.
(3)科研獲獎
●中國產學研合作促進會產學研合作創新成果優秀獎,陸相致密砂巖強非均質油氣藏長效酸化改造技術及重大應用,4/10,2019
●中國石油和化工自動化應用協會科技進步二等獎,低成本高性能壓裂酸化工作液關鍵技術及應用,2/8,2021
●中國石油和化工學工業聯合會科技進步三等獎,超高溫儲層增產改造化學轉向技術及應用,3/5,2022
主要從事油氣藏增產改造中工作液體系包括各種類型的壓裂液體系、酸化(壓)液體系及儲層重復改造中暫堵劑材料及配套工藝的研究。
●油氣藏增產改造壓裂液體系:壓裂液是水力壓裂過程中的工作液,起著傳遞壓力、形成和延伸裂縫、攜帶支撐劑的作用,它的性能在很大程度上決定了壓裂施工的成敗,隨著油氣儲層變得越來越復雜、非常規油氣藏的開發,對壓裂液的要求也越來越高,例如耐(超)高溫壓裂液、清潔壓裂液、加重壓裂液、耐礦化度壓裂液、低摩阻滑溜水等。
●油氣藏增產改造酸化(壓)液體系:酸化(壓)作為儲層解堵、增產的重要手段,常規的酸液體系已無法滿足日益復雜的儲層條件,需要開展耐(超)高溫的稠化酸、轉向酸、緩速酸等一系列功能性酸液體系的研發。
●儲層重復改造中的暫堵劑材料及配套工藝:對于天然裂縫發育或者經過前期增產改造的儲層,為了進一步提高增產改造效果,溝通新的油氣儲集體,需要對原有裂縫進行暫時性封堵,迫使后續改造裂縫轉向,需要對暫堵劑材料和暫堵工藝進行研究,包括暫堵劑類型、尺寸、性能及組合參數等。
本團隊共有4名固定老師,包括毛金成教授,林沖博士,張陽博士,涵蓋油田化學、有機合成、聚合物合成、分子模擬、巖石力學、增產改造工藝等研究方向。
