宋兆杰

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  • 所在单位:
    非常规油气科学技术研究院/提高采收率研究所
  • 所在学科:
    石油与天然气工程
  • 个人学位:
    博士
  • 职称名称:
    研究员(自然科学)
  • 教师类别:
    专任教师
  • 导师类型:
    博士生导师,硕士生导师
  • 招生专业:
    石油与天然气工程
  • 电子邮箱:
    songz@cup.edu.cn
  • 联系方式:
    010-89739187

教育经历

  • 2010-09至2014-06, 中国地质大学(北京), 油气田开发工程, 博士研究生
  • 2012-09至2014-06, 密苏里科技大学, 石油工程, 博士研究生
  • 2007-09至2010-06, 中国石油大学(北京), 油气田开发工程, 硕士研究生
  • 2003-09至2007-06, 中国石油大学(华东), 材料成型及控制工程, 大学本科

个人概况


办公室:主楼A座A302

个人简介
学校优秀青年学者、青年拔尖人才,研究员,博导、硕导,非常规油气科学技术研究院副院长。2014年获得中国地质大学(北京)油气田开发工程专业博士学位。2012-2014年于美国密苏里科技大学进行交流访问。主要研究方向包括:非常规油气相态与提高采收率、CO2驱油与地质封存(CCUS)、多孔介质多相流体流动规律、纳米智能驱油等。主持国家自然科学基金3项、国家重点研发计划专题1项、中国石油科技创新基金1项、校级基金2项,参与完成或正在参与多个国家科技重大专项课题和油田横向课题等。在Chemical Engineering Journal、Fuel和石油勘探与开发等国内外高水平期刊或会议共发表论文60余篇,已授权发明专利10余件,获得过省部级科技进步一等奖2项(个人分别排名第1、第9)、领跑者5000——中国精品科技期刊顶尖学术论文(F5000)等奖励与荣誉。现为SPE会员、中国石油学会会员、Geofluids期刊编委/学术编辑、Petroleum Science期刊青年编委等。

研究方向
[1] 非常规油气相态与提高采收率
[2] 二氧化碳驱油与地质封存(CCUS)
[3] 多孔介质多相流体流动规律
[4] 纳米智能驱油

工作经历
2021.07-,中国石油大学(北京),研究员
2021.08-2024.07,中国石油大学(北京),学校优秀青年学者
2016.06-2021.07,中国石油大学(北京),副研究员
2015.08-2018.07,中国石油大学(北京),学校青年拔尖人才
2014.07-2016.06,中国石油大学(北京),助理研究员

荣获奖励
[1] 2020.12,中国石油和化工自动化行业科技进步一等奖(排名第1)
[2] 2020.12,Petroleum Science期刊优秀青年编委
[3] 2015.10,中国石油和化学工业联合会科技进步一等奖(排名第9)
[4] 2014.10,领跑者5000——中国精品科技期刊顶尖学术论文(F5000)
[5] 2014.06,中国地质大学(北京)优秀博士学位论文

科研项目
[17] 2021.01-2024.12,页岩油储层纳微米孔喉中油-CO2-水多元体系相行为与流动机制研究(52074319),国家自然科学基金面上项目,主持
[16] 2020.01-2024.12,准噶尔盆地玛湖中下组合和吉木萨尔陆相页岩油高效勘探开发理论及关键技术研究(ZLZX2020-01),中石油战略合作科技专项,副课题长
[15] 2020.01-2023.12,深层碳酸盐岩酸性气藏数值模拟与注气控水技术(U19B6003-02-05-02),国家自然科学基金联合基金项目任务,主持
[14] 2019.11-2021.11,不同类型岩石孔隙结构表征方法研究(33550000-19-ZC0607-0019),中国石化石油勘探开发研究院技术服务项目,主持
[13] 2018.12-2019.10,巴西Libra碳酸盐岩油藏富CO2混相驱气窜规律研究(RIPED-2018-JS-688),中国石油勘探开发研究院技术服务项目,主持
[12] 2018.05-2021.04,低渗透油藏CO2驱油与封存协同方案设计及跟踪评价研究(2018YFB060550501),国家重点研发计划专题,主持
[11] 2016.01-2018.12,缝洞型碳酸盐岩油藏多相流体流动规律与剩余油形成机理研究(51504268),国家自然科学基金青年科学基金,主持
[10] 2015.10-2017.09,压裂液中减阻剂与致密砂岩的相互作用及其对油水渗透率的影响(2015D-5006-0209),中国石油科技创新基金,主持
[9] 2015.08-2018.07,缝洞型碳酸盐岩油藏提高采收率技术研究(2462014YJRC053),中国石油大学(北京)拔尖人才科研启动基金,主持
[8] 2015.01-2017.12,缝洞型碳酸盐岩油藏注水窜逸规律研究(2462015YQ1105),中国石油大学(北京)优秀青年教师研究项目,主持
[7] 2017.01-2020.12,低渗-致密油藏高效提高采收率新技术(2017ZX05009-004),国家科技重大专项课题,科研骨干
[6] 2016.01-2020.12,缝洞型油藏泡沫辅助气驱提高采收率技术研究(2016ZX05014-004-004),国家科技重大专项专题,技术首席
[5] 2016.07-2017.06,长庆油田CO2驱气窜规律分析与工艺对策研究(16CY2-FW-003),中国石油长庆油田技术服务项目,科研骨干
[4] 2014.07-2016.09,CO2埋存与提高采收率评价研究(2012BAC26B02),国家科技支撑计划项目,科研骨干
[3] 2014.07-2015.01,扶余油田优势通道微观形态及形成机理研究(JS13-W-14-JZ-26-47),中国石油吉林油田技术服务项目,科研骨干
[2] 2013.01-2014.04,Effect of Polymer/Polymer Gel on Disproportionate Permeability Reduction to Gas and Water for Tight Gas,美国化学会石油研究基金,科研骨干
[1] 2010.09-2014.07,CO2驱油与埋存潜力评价及战略规划(2011ZX05016-006),国家科技重大专项课题,科研骨干

代表性论文(第一作者/通讯作者)
期刊论文
[30] Effect of confinement on the three-phase equilibrium of water-oil-CO2 mixtures in nanopores, Petroleum Science, 2022.
[29] The viscosifying behavior of W/O emulsion and its underlying mechanisms: Considering the interfacial adsorption of heavy components, Colloids and Surfaces A, 2022.
[28] Water-based nanofluid-alternating-CO2 injection for enhancing heavy oil recovery: Considering oil-nanofluid emulsification, Journal of Petroleum Science and Engineering, 2021.
[27] Phase Behavior and Miscibility of CO2-Hydrocarbon Mixtures in Shale Nanopores, Industrial & Engineering Chemistry Research, 2021.
[26] Effect of Nanopore Confinement on Fluid Phase Behavior and Production Performance in Shale Oil Reservoir, Industrial & Engineering Chemistry Research, 2021.
[25] Wettability effects on phase behavior and interfacial tension in shale nanopores, Fuel, 2021.
[24] Adsorption induced critical shifts of confined fluids in shale nanopores, Chemical Engineering Journal, 2020.
[23] A critical review of CO2 enhanced oil recovery in tight oil reservoirs of North America and China, Fuel, 2020.
[22] Phase Behavior of Hydrocarbon Mixture in Shale Nanopores Considering the Effect of Adsorption and Its Induced Critical Shifts, Industrial & Engineering Chemistry Research, 2020.
[21] Gas injection for enhanced oil recovery in two-dimensional geology-based physical model of Tahe fractured-vuggy carbonate reservoirs: karst fault system, Petroleum Science, 2020.
[20] Effect of vug filling on oil-displacement efficiency in carbonate fractured-vuggy reservoir by natural bottom-water drive: A conceptual model experiment, Journal of Petroleum Science and Engineering, 2019.
[19] Experimental study on disproportionate permeability reduction caused by non-recovered fracturing fluids in tight oil reservoirs, Fuel, 2018.
[18] Preformed particle gel propagation and dehydration through semi-transparent fractures and their effect on water flow, Journal of Petroleum Science and Engineering, 2018.
[17] Conformance control for CO2-EOR in naturally fractured low permeability oil reservoirs, Journal of Petroleum Science and Engineering, 2018.
[16] Using screen models to evaluate the injection characteristics of particle gels for water control, Energy & Fuels, 2018.
[15] Effect of polymer on disproportionate permeability reduction to gas and water for fractured shales, Fuel, 2015.
[14] Effect of polymer on gas flow behavior in microfractures of unconventional gas reservoirs, Journal of Natural Gas Science and Engineering, 2015.
[13] D-optimal design for Rapid Assessment Model of CO2 flooding in high water cut oil reservoirs, Journal of Natural Gas Science and Engineering, 2014.
[12] Sensitivity analysis of water-alternating-CO2 flooding for enhanced oil recovery in high water cut oil reservoirs, Computers & Fluids, 2014.
[11] Derivation of water flooding characteristic curve for high water-cut oilfields, Petroleum Exploration and Development, 2013.
[10] 深水浊积岩油藏提高采收率方法研究——以安哥拉X油藏为例,石油钻探技术,2021.
[9] 纳米颗粒在岩石表面吸附—脱附规律研究,石油科学通报,2020.
[8] 致密储集层压裂液与致密砂岩相互作用研究,地质与勘探,2019.
[7] 缝洞型油藏裂缝内油水两相流动特征研究,西安石油大学学报(自然科学版),2018.
[6] 稠油油藏注超临界二氧化碳驱油影响因素分析,地质与勘探,2017.
[5] 轻质油藏注空气提高采收率技术适应性探讨,中国矿业,2016.
[4] 考虑纵向非均质性的底水气藏临界产量计算方法,科学技术与工程,2015.
[3] 高含水期油田水驱特征曲线关系式的理论推导,石油勘探与开发,2013.
[2] 水驱油藏转注CO2驱油参数优化与效果评价,西安石油大学学报(自然科学版),2012.
[1] 考虑非达西渗流的底水锥进临界产量计算模型,石油学报,2012.
会议论文或报告
[18] 页岩油储层提高采收率机理与方法探讨, 第五届提高采收率国际会议(特邀报告/分会主持人),2021.
[17] 页岩油储层提高采收率机理与技术探讨,第五届全国油气藏提高采收率技术研讨会(特邀报告/分会主持人),2021.
[16] Adsorption Behavior of Shale Oil in Slit Pores and Its Underlying Mechanisms: Insights from Molecular Dynamic Simulation, presented at 2020 AIChE Annual Meeting, 2020.
[15] Phase behavior and minimum miscibility pressure of confined fluids in organic nanopores, SPE 200449 presented at SPE Improved Oil Recovery Conference, 2020.
[14] Confinement Effect on the Fluid Phase Behavior and Flow in Shale Oil Reservoirs, URTeC 3135 presented at SPE/AAPG/SEG Unconventional Resources Technology Conference, 2020.
[13] 页岩纳米孔内烃类流体相行为研究,第四届全国油气藏提高采收率技术研讨会(特邀报告/分会主持人),2020.
[12] Phase equilibria of confined fluids in nanopores of shale rocks from an adsorption-dependent equation of state, presented at 2019 AIChE Annual Meeting, 2019.
[11] A critical review of CO2 enhanced oil recovery in tight oil reservoirs of North America and China, SPE 196548 presented at SPE/IATMI Asia Pacific Oil & Gas Conference and Exhibition, 2019.
[10] Modifying peng-robinson equation of state to consider influence of confinement on fluid phase behavior, presented at Carbon Management Technology Conference, 2019.
[9] Experimental modeling of gas channeling for water-alternating-gas flooding in high-temperature and high-pressure reservoirs, presented at Carbon Management Technology Conference, 2019.
[8] Effect of water-alternating-gas injection on gas and water production control in carbonate reservoirs, presented at Carbon Management Technology Conference, 2019.
[7] Recognition on gas channeling characteristics during CO2 flooding in low permeability reservoirs, presented at 2nd International Symposium on Oilfield Chemistry (Invited Speaker/Session Host), 2018.
[6] 低渗透油藏二氧化碳驱油气窜规律与防治措施研究,第二届全国油气藏提高采收率技术研讨会(特邀报告/大会主持人),2018.
[5] Fracturing fluid retention and its effect on fluid flow in microfractures of tight oil reservoirs, presented at 2017 AIChE Annual Meeting, 2017.
[4] Nitrogen gas flooding for naturally fractured carbonate reservoir: Visualisation experiment and numerical simulation, SPE 182479 presented at SPE Asia Pacific Oil & Gas Conference and Exhibition, 2016.
[3] Mechanism and applications of high-pressure air injection in light oil reservoirs, Presented at 2016 International Conference on New Energy and Sustainable Development, 2016.
[2] D-optimal design for Rapid Assessment Model of CO2 flooding in high water cut oilfields, Presented at 2014 International Conference on Enhanced Oil Recovery, 2014.
[1] 考虑纵向非均质性的底水气藏临界产量计算方法,第八届北京石油青年学术年会,2010.

专利
[17] 一种致密砂岩渗吸效果评价方法及装置,ZL202010082639.4
[16] 油气最小混相压力确定方法及装置,ZL202010105946.X
[15] 一种确定页岩孔径分布的方法、装置、设备及系统,ZL202010289460.6
[14] 岩心夹持器,ZL201910967950.4
[13] 一种注气驱油实验流体的确定方法及装置,ZL201910879964.0
[12] CO2驱油技术效果的评价方法及装置,ZL201811043315.9
[11] 缝洞型碳酸盐岩油藏缝洞分布图的建立方法及模型和应用,ZL201810520795.7
[10] 一种微分散凝胶强化泡沫体系及评价方法,ZL201710992894.0
[9] 模拟致密油藏裂缝内流体流动的可视化模型及制备和应用,ZL 201711005687.8
[8] 一种泡沫综合性能评价方法,ZL201710991873.7
[7] 一种水驱油田优势通道形成机理及发育情况的分析方法,ZL201510084039.0
[6] 缝洞型油藏三维可视化模型及其制作方法,ZL201511006046.5
[5] 模拟缝洞型碳酸盐岩油藏注气的可视化实验装置及方法,ZL201510724935.9
[4] 一种表征缝洞型油藏水驱开采效果的方法,ZL201510440959.1
[3] 缝洞型碳酸盐岩油藏物理模型、驱替模拟实验装置及系统,ZL201510712835.4
[2] 一种分级控制流度的CO2驱油藏开采方法,ZL201510309517.3
[1] 用于低渗透砂岩油藏的驱油实验装置及方法,ZL201510236158.3

学术兼职
[1] 国际石油工程师协会(SPE)会员
[2] 中国石油学会(CPS)会员
[3] Geofluids期刊编委/学术编辑
[4] Petroleum Science期刊青年编委
[5] 2021 Unconventional Resources Technology Conference评委
[6] SPE J,Fuel,Energy & Fuels,Journal of Petroleum Science and Engineering,Journal of Natural Gas Science and Engineering,Petroleum Science,Energy Reports,European Physical Journal Plus,Journal of Unconventional Oil and Gas Resources,International Journal of Oil, Gas and Coal Technology,石油勘探与开发等学术期刊审稿人