姓名: 于海洋
職稱: 教授,、博士生導(dǎo)師
教育與工作經(jīng)歷:
2001-2005 大連理工大學(xué) 動力工程 本科
2005-2008 清華大學(xué) 熱能工程 碩士
2008-2012 美國德州大學(xué)奧斯汀分校(UT-Austin) 石油工程 博士
2012-2015 中國石油大學(xué)(北京) 講師,,校青年拔尖人才
2015-2020 中國石油大學(xué)(北京) 副教授
2020至今 中國石油大學(xué)(北京) 教授
電子郵箱: haiyangyu.cup@139.com
聯(lián)系電話: 010-89733032
所在系所: 石油工程學(xué)院,、碳中和示范性能源學(xué)院
研究方向: 非常規(guī)油氣滲流與提高采收率,、二氧化碳高效利用及封存
教學(xué)情況: 本科課程《油層物理》,、《提高采收率》,、《氣藏工程》
研究生課程《高等油層物理》
科研教學(xué)榮譽獎勵:
[1] 國家級青年人才,,2021.
[2] 中國石油和化工自動化行業(yè)協(xié)會技術(shù)發(fā)明一等獎,,2020(排名第二):致密氣藏非均勻?qū)Я髂芰毫丫a(chǎn)量和壓力分析技術(shù)及應(yīng)用
[3] 中國石油和化工自動化行業(yè)協(xié)會科技進(jìn)步一等獎,,2020(排名第八):超低滲油藏動態(tài)裂縫模擬與高效排驅(qū)關(guān)鍵技術(shù)及規(guī)模應(yīng)用
[4] 陜西省科技進(jìn)步二等獎,,2020(排名第四):鄂爾多斯盆地西部多層系特低滲油藏高效開發(fā)技術(shù)突破及規(guī)模應(yīng)用
[5] 中國石油和化學(xué)工業(yè)聯(lián)合會科技進(jìn)步獎二等獎, 2019(排名第二):超/特低滲透油藏裂縫動態(tài)表征與開發(fā)調(diào)整應(yīng)用
[6] 中國石油學(xué)會石油工程專業(yè)委員會,,優(yōu)秀會議論文一等獎,, 2018
[7] 中國石油學(xué)會海洋石油分會,優(yōu)秀會議論文獎,, 2018
[8] 中國石油學(xué)會,,第十屆青年學(xué)術(shù)年會優(yōu)秀論文特等獎, 2017
[9] 中國石油大學(xué)(北京)2020-2022學(xué)年度優(yōu)秀教師,,2022
[10] 校級教學(xué)成果一等獎,,2021、2019
[11] 中國石油工程設(shè)計大賽優(yōu)秀指導(dǎo)教師,2021
[12] 首批國家級一流本科課程《油層物理》,,2020
[13] 中國石油大學(xué)(北京)科技創(chuàng)新優(yōu)秀指導(dǎo)教師,,2020
[14] 中國石油大學(xué)(北京)石油工程學(xué)院院長獎-最佳貢獻(xiàn)獎, 2015
[15] 中國石油大學(xué)(北京)青年教學(xué)骨干教師,, 2015
[16] 中國石油大學(xué)(北京)青年拔尖人才,, 2012
[17] SPE提高采收率年會最佳論文獎, 2010
主持縱向項目(項目負(fù)責(zé)人):
[1] 中組部國家級人才支撐項目,,非常規(guī)油氣滲流與提高采收率,,2021.12-2026.12
[2] 國家自然科學(xué)基金-面上項目,頁巖油注天然氣開發(fā)油氣兩相滲流微尺度效應(yīng)及增油機(jī)理,, 2021.01-2024.12
[3] 國家自然科學(xué)基金-面上項目,,致密油藏碳化水驅(qū)提高采收率機(jī)理研究,2019.01-2022.12
[4] 國家自然科學(xué)基金-石油化工聯(lián)合基金,,致密油藏同井縫間注采機(jī)理研究,,2018.01-2020.12
[5] 國家自然科學(xué)基金-青年基金,含油多孔介質(zhì)中超磁性納米顆粒的傳遞機(jī)理研究,,2014.01-2016.12
[6] “十三五”國家科技重大專項子課題,,致密油藏碳化水+表面活性劑驅(qū)采油技術(shù)研究, 2017.01-2020.06
[7] “十三五”國家科技重大專項子課題,,分段壓裂水平井油藏工程方法研究,,2017.01-2020.12
[8] 國家重點研發(fā)計劃子課題,典型行業(yè)企業(yè)能源管理績效參數(shù)指標(biāo)體系及績效提升途徑研究,,2016.07-2018.12
[9] 油氣資源與探測國家重點實驗室基金,,二氧化碳提高頁巖油采收率及埋存機(jī)理,2021.12-2023.12
[10] 頁巖油氣富集機(jī)理與有效開發(fā)國家重點實驗室基金,,頁巖油CO2吞吐采油技術(shù)研究,,2018.08-2019.07
[11] 校基金-學(xué)院自主項目,,微納米孔隙油氣流動微尺度效應(yīng),,2020.1-2022.12
[12] 校青年拔尖人才基金,超磁性納米顆粒傳遞機(jī)理及聚合物驅(qū)試井研究,,2013.01-2015.12
主持橫向課題(項目負(fù)責(zé)人):
[1] 盆5井區(qū)儲層污染綜合治理技術(shù)研究,,中石油新疆油田,2022.8-2024.6
[2] 超低滲透油藏注CO2開發(fā)技術(shù)政策研究,,中石油長慶油田,,2022.7-2023.12
[3] 超低滲油藏水平井滲流距離測試及壓裂裂縫間距評價優(yōu)化,中石油長慶油田,,2022.7-2022.12
[4] 二氧化碳微氣泡在驅(qū)油-封存過程中的溶解動力學(xué)和穩(wěn)定性實驗研究,,中石化工程院,,2021.9-2022.8
[5] 碳化水強(qiáng)化滲吸置換效率與二氧化碳埋存可行性實驗研究,中石油長慶油田,,2021.9-2022.6
[6] 中東油田流體物性實驗、參數(shù)測定及水驅(qū)油實驗,,中石油勘探院,,2021.4-2021.12
[7] 侏羅系底水油藏控水材料基礎(chǔ)實驗研究,中石油長慶油田,,2021.02-2021.12
[8] 超高壓裂縫性致密揮發(fā)油藏早期合理開發(fā)技術(shù)研究,,中石油塔里木油田,2020.10-2023.9
[9] 超低滲-致密油儲層注烴類氣體補充能量方式可行性實驗評價,,中石油長慶油田,, 2019.08-2020.10
[10] 致密巖心高溫高壓滲吸機(jī)理研究,中石油勘探院,,2019.10-2020.08
[11] 水平井同井縫間注采可行性研究,,中石油大慶油田,2018.11-2019.08
[12] 特低滲氣田滲流機(jī)理研究,,中海油上海分公司,,2015.12-2016.12
社會與學(xué)術(shù)兼職:
[1] 國家領(lǐng)軍期刊《Petroleum Science》副主編
[2] 中國工程院院刊《Engineering》青年編委
[3] 核心期刊《石油科學(xué)通報》執(zhí)行編委
[4] 國家標(biāo)準(zhǔn)化管理委員會能源管理分技術(shù)委員會 委員
[5] 國際標(biāo)準(zhǔn)化組織(ISO)工作組專家
[6] 浙江清華長三角研究院 客座研究員
[7] 中國石油大學(xué)(北京)石工學(xué)院學(xué)術(shù)委員會 委員
[8] 中國石油大學(xué)(北京)油氣田開發(fā)學(xué)科學(xué)術(shù)帶頭人助理
[9] 教育部博士論文評審專家
[10] 國家自然科學(xué)基金項目審評專家
[11] 美國石油工程師學(xué)會 會員
代表性期刊論文:
[1] Numerical study on natural gas injection with allied in-situ injection and production for improving shale oil recovery. Fuel, 2022.
[2] Experimental investigation on plugging performance of nanospheres in low-permeability reservoir with bottom water. Advances in Geo-Energy Research, 2022.
[3] Extraction of shale oil with supercritical CO2: Effects of number of fractures and injection pressure. Fuel, 2021.
[4] Applications of Artificial Intelligence in Oil and Gas Development. Archives of Computational Methods in Engineering, 2021.
[5] Experimental study on EOR performance of CO2-based flooding methods on tight oil. Fuel, 2021.
[6] Three-Dimensional Numerical Simulation of Multiscale Fractures and Multiphase Flow in Heterogeneous Unconventional Reservoirs with Coupled Fractal Characteristics. Geofluids, 2021.
[7] Determination of minimum near miscible pressure region during CO2 and associated gas injection for tight oil reservoir in Ordos Basin China. Fuel, 2020.
[8] Semi-analytical Modelling of Water Injector Test with Fractured Channel in Tight Oil Reservoir. Rock Mechanics and Rock Engineering, 2020.
[9] Feasibility Study of Improved Unconventional Reservoir Performance with Carbonated Water and Surfactant. Energy, 2019.
[10] Application of Cumulative-in-situ-injection-production Technology to Supplement Hydrocarbon Recovery Among Fractured Tight Oil Reservoirs: A Case Study in Changqing Oilfield, China. Fuel, 2019.
[11] Interference well-test model for vertical well with double-segment fracture in a multi-well system. Journal of Petroleum Science and Engineering, 2019.
[12] Interference testing model of multiply fractured horizontal well with multiple injection wells. Journal of Petroleum Science and Engineering, 2019.
[13] Pressure-Transient Analysis of Water Injectors Considering the Multiple Closures of Waterflood-Induced Fractures in Tight Reservoir: Case Studies in Changqing Oilfield China. Journal of Petroleum Science and Engineering, 2019.
[14] A compositional model for CO2 flooding including CO2 equilibria between water and oil using the Peng-Robinson equation of state with the Wong-Sandler mixing rule. Petroleum Science, 2019.
[15] Simulation study of allied in-situ injection and production for enhancing shale oil recovery and CO2 emission control. Energies, 2019.
[16] Analytical interference testing analysis of multi-segment horizontal well. Journal of Petroleum Science and Engineering, 2018.
[17] An Innovative Model to Evaluate Fracture Closure of Multi-Fractured Horizontal Well In Tight Gas Reservoir Based on Bottom-Hole Pressure. Journal of Natural Gas Science and Engineering, 2018.
[18] A Novel Well-Testing Model to Analyze Production Distribution of Multi-Stage Fractured Horizontal Well. Journal of Natural Gas Science and Engineering, 2018.
[19] A Semianalytical Methodology to Diagnose the Locations of Underperforming Hydraulic Fractures Through Pressure-Transient Analysis in Tight Gas Reservoir. SPE Journal, 2017.
[20] The Physical Process and Pressure-Transient Analysis Considering Fractures Excessive Extension in Water Injection Wells. Journal of Petroleum Science and Engineering, 2017.
[21] Semi-Analytical Modeling for Water Injection Well in Tight Reservoir Considering the Variation of Waterflood-Induced Fracture Properties–Case Studies in Changqing Oilfield China. Journal of Petroleum Science and Engineering, 2017.
[22] A Semianalytical Approach to Estimate Fracture Closure and Formation Damage of Vertically Fractured Wells in Tight Gas Reservoir. Journal of Petroleum Science and Engineering, 2016.
[23] Investigation of Nanoparticle Adsorption During Transport in Porous Media. SPE Journal, 2015.
[24] Flow enhancement of water-based nanoparticle dispersion through microscale sedimentary rocks. Scientific Reports, 2015.
[25] Well testing interpretation method and application in triple‐layer reservoirs by polymer flooding. Materialwissenschaft Und Werkstofftechnik, 2015.
[26] Transport and retention of aqueous dispersions of superparamagnetic nanoparticles in sandstone. Journal of Petroleum Science and Engineering, 2014.
[27] 裂縫性非均質(zhì)致密儲層自適應(yīng)應(yīng)力敏感性研究. 石油鉆探技術(shù), 2022.
[28] 致密砂巖逆向滲吸作用距離實驗研究. 力學(xué)學(xué)報, 2021.
[29] 碳化水驅(qū)提高采收率研究進(jìn)展. 石油科學(xué)通報, 2020.
[30] 致密油藏碳化水驅(qū)提高采收率方法. 大慶石油地質(zhì)與開發(fā), 2019.
[31] 水平井同井注采技術(shù). 大慶石油地質(zhì)與開發(fā), 2019.
[32] 壓裂水平井裂縫和水平井筒不規(guī)則產(chǎn)油試井分析. 大慶石油地質(zhì)與開發(fā), 2018.
[33] 致密油藏多級壓裂井異井異步注采可行性研究. 石油科學(xué)通報, 2018.
[34] 能源管理體系評價指標(biāo)與應(yīng)用現(xiàn)狀分析. 中國標(biāo)準(zhǔn)化, 2018.
[35] 致密油藏多級壓裂水平井同井縫間注采可行性. 石油學(xué)報, 2017.
[36] 多段壓裂水平井不均勻產(chǎn)油試井模型. 中國石油大學(xué)學(xué)報:自然科學(xué)版, 2017.
[37] ISO50006,、ISO50015與ISO50047的比較與探究. 標(biāo)準(zhǔn)科學(xué), 2016.
代表性會議論文:
[1] Application of inter-fracture injection and production in a cluster well to enhance oil recovery. SPE Annual Technical Conference and Exhibition, 2019.
[2] Allied in-situ injection and production for fractured horizontal wells to increase hydrocarbon recovery in tight oil reservoirs: a case study in Changqing Oilfield. International Petroleum Technology Conference, 2019.
[3] A Novel Multi-Well Interference Testing Model of a Fractured Horizontal Well and Vertical Wells. SPE Annual Technical Conference and Exhibition, 2018.
[4] Case Studies: Pressure-Transient Analysis for Water Injector with the Influence of Waterflood-Induced Fractures in Tight Reservoir. SPE Improved Oil Recovery Conference, 2018.
[5] Estimation of Non-Uniform Production Rate Distribution of Multi-Fractured Horizontal Well Through Pressure Transient Analysis: Model and Case Study. SPE Annual Technical Conference and Exhibition, 2017.
[6] A Novel Well Testing Inversion Method for Characterization of Non-Darcy Flow Behavior in Low Permeability Reservoirs. SPE Annual Technical Conference and Exhibition, USA, 2017.
[7] Successful Application of Well Testing and Electrical Resistance Tomography to Determine Production Contribution of Individual Fracture and Water-Breakthrough Locations of Multifractured Horizontal Well in Changqing Oil Field,, China. SPE Annual Technical Conference and Exhibition, 2017.
[8] Transport and Retention of Aqueous Dispersions of Paramagnetic Nanoparticles in Reservoir Rocks. SPE Improved Oil Recovery Symposium, 2010.
國家發(fā)明專利(排名第1):
[1] 動態(tài)滲吸裝置和用于動態(tài)滲吸實驗的實驗方法. ZL201811482680.X,2022年授權(quán)
[2] 用于確定通過萃取實驗萃取出的油量的方法和裝置. ZL201911215681.2,,2020年授權(quán)
[3] 高溫高壓條件下強(qiáng)化碳化水的滲吸系統(tǒng). ZL201711054256.0,,2020年授權(quán)
[4] 用于確定碳化水驅(qū)油過程中碳化水對儲層傷害程度的方法. ZL201910187496.0,2020年授權(quán)
[5] 水平井井下氣液分離井上回注采油系統(tǒng)及其方法. ZL201810032101.5,,2020年授權(quán)
[6] 水平井井下氣液分離回注采油系統(tǒng)及其方法. ZL201810032637.7,,2020年授權(quán)
[7] 滲吸萃取裝置及滲吸萃取實驗方法. ZL201810980994.6,2020年授權(quán)
[8] 高溫高壓條件下碳化水的驅(qū)替系統(tǒng)及其方法. ZL201711046782.2,,2020年授權(quán)
[9] 注水誘發(fā)微裂縫二維擴(kuò)展的物理模擬實驗方法. ZL201710735940.9,,2019年授權(quán)
[10] 拉鏈?zhǔn)讲伎p的雙壓裂水平井異井異步注水采油方法. ZL201710078828.2,2019年授權(quán)
[11] 對稱式布縫的分組異井異步注CO2采油方法. ZL201710078827.8,,2019年授權(quán)
[12] 對稱式布縫的異井異步注CO2采油方法. ZL201710078521.2,,2019年授權(quán)
[13] 多級壓裂水平井縫間間隔CO2驅(qū)采油方法. ZL201610564574.0,2018年授權(quán)
[14] 多級壓裂水平井縫間間隔注水吞吐采油方法. ZL201610253549.0,,2018年授權(quán)
[15] 多級壓裂水平井縫間間隔注水吞吐采油方法. ZL201610195661.3,,2018年授權(quán)
[16] 水平井多參數(shù)組合找水測量裝置. ZL201510730997.0,2018年授權(quán)
[17] 利用地震縱波傳播時間預(yù)測地層孔隙壓力的方法. ZL201510166143.4,,2017年授權(quán)
起草標(biāo)準(zhǔn):
國家標(biāo)準(zhǔn)GB/T39532-2020《能源績效測量和驗證指南》
國家標(biāo)準(zhǔn)GB/T39775-2021《能源管理績效評價導(dǎo)則》
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