當前位置: 油氣藏工程研究所
侯健 教授
作者: 發布者:趙小明 發布時間:2023-03-15 訪問次數:25541

職稱:教授

單位:油氣藏工程研究所

最高學曆/學位:博士

學科:油氣田開發工程學科,海洋油氣工程學科,石油與天然氣工程領域

所學專業:油氣田開發工程

電子郵箱:houjian@upc.edu.cn

聯係電話:0532-86983873

地址郵編:山東省青島市黃島區長江西路66號必威app精裝版客服 ,266580

  • 個人主頁
  • 學習與工作經曆
    1989.9-1993.6,中國石油大學(華東),油藏工程學士;
    1993.9-1996.6,中國石油大學(華東),油氣田開發工程碩士;
    1999.9-2002.6,中國石油大學(華東),油氣田開發工程博士。
  • 研究方向
    油氣滲流理論、化學驅開發理論、稠油熱采開發理論、非常規油氣開發技術及理論
  • 招生方向
  • 主講課題
    《滲流力學》、《注蒸汽熱力采油》、《油藏數值模擬基礎》、《石油工業概論》
  • 學術兼職
    國家自然科學基金、國家科技部項目及獎勵評審專家
    《石油科學通報》副主編、《滲流力學進展》、《中國石油大學學報》編委
  • 指導研究生
    在讀或畢業研究生72名
    博士招生專業:
    油氣田開發工程(學術學位博士)
    01 油氣滲流理論與方法
    02 油氣田開發理論與方法
    04 化學法提高采收率理論與技術
    05 油氣田信息化與智能開發方法
    石油與天然氣工程(專業學位博士)
    02 油氣田開發工程
    碩士招生專業:
    石油與天然氣工程(學術、專業碩士)
    03 滲流理論與油氣藏開發工程
    06 油氣工程信息與智能技術
    07 非常規地質能源開發工程理論與技術
    08 地下儲碳儲能理論與技術
  • 承擔科研課題
    承擔國家自然科學基金重點基金、國家重點研發計劃、國家油氣重大專項、國家863計劃等項目50餘項,代表性項目如下:
    [1] 國家自然科學基金聯合基金重點項目,U21B2070、柔性膠囊聚合物驅提高采收率的基礎理論研究、2022/01-2025/02、主持;
    [2] 國家重點研發計劃課題,2018YFAO702404、稠油化學複合冷采滲流機理及油藏數值模擬方法、2019/09-2024/08、主持;
    [3] 中石油重大科技項目課題,ZD2019-184-002、天然氣水合物藏開采機理及儲層改造輔助開發方法、2019/01-2023/12 、主持;
    [4] 國家傑出青年基金,51625403、油氣藏滲流力學與提高采收率方法、2017/01-2021/12、主持;
    [5] 國家自然科學基金麵上項目,51574269、預交聯凝膠顆粒分散體係微觀滲流的LBM-DEM模擬方法研究、2016/01-2019/12、主持;
    [6] 國家油氣重大專項專題,2016ZX05011-003-008、化學驅動態預警方法及油藏工程研究、2016/01-2020/12、主持;
    [7] 國家油氣重大專項專題,2016ZX05025-003-006、海上油田全過程提高采收率模式與優化研究、2016/01-2020/12、主持;
    [8] 國家自然科學基金麵上項目,10972237、泡沫複合驅油體係在多孔介質中的穩定特征及滲流機製研究、2010/01-2012/12、主持;
    [9] 國家自然科學基金麵上項目,10772200、非牛頓流體在多孔介質中微觀滲流的實驗和模擬研究、2008/01-2010/12、主持;
    [10] 國家自然科學基金青年科學基金項目,10302021、聚合物驅微觀滲流機理及剩餘油啟動臨界參數研究、2004/01-2004/12、主持;
    [11] 國家油氣重大專項專題,2011ZX05011-004-008HZ、化學驅效果評價方法研究、2011/01-2015/12、主持;
    [12] 國家油氣重大專項專題,2011ZX05024-004-13、海上油田提高采收率潛力評價及開發方式優化技術研究、2011/01-2015/12、主持;
    [13] 國家油氣重大專項專題,2008ZX05011-006-012、高溫高鹽油藏化學驅效果評價及定量表征技術研究、2008/06-2010/12、主持;
    [14] 中國博士後科學基金特別資助項目,200902180、儲層參數協同時變對開發規律影響的多尺度模擬研究、2009/09-2010/10、主持;
    [15] 中國博士後科學基金麵上一等資助項目,20080440058、無堿高效泡沫複合驅油體係在多孔介質中流動機製研究、2008/12-2009/12、主持;
    [16] 國家“863”項目,2007AA06Z216、高溫高鹽油藏無堿高效泡沫複合驅油體係研究、2007/12-2010/12、副組長;
    [17] 教育部新世紀優秀人才支持計劃,NCET-11-0734、2012/01-2014/12、主持;
    [18] 山東省自然科學傑出青年基金項目,JQ201115、微觀滲流實驗與模擬、 2011/07-2014/07、主持。
  • 獲獎情況
    [1] 勝利油田邊際稠油高效開發技術與應用(國家科學技術進步獎二等獎),中華人民共和國,2011,6/10.
    [2] 深層稠油油藏多元流體輔助高壓蒸汽驅關鍵技術及應用(中國石油和化學工業協會科技進步一等獎),中國石油和化學工業協會,2021,1/15.
    [3] 非均相複合驅大幅度提高石油采收率的理論與實踐(中國石油和化學工業聯合會技術發明一等獎),中國石油和化學工業協會,2017,5/10.
    [4] 化學驅滲流理論與開發技術及其在高含水油田的工業化應用(中國石油和化學工業聯合會科學技術一等獎),中國石油和化學工業聯合會,2013,1/15.
    [5] 聚驅後地層殘留聚合物再利用提高采收率技術研究與應用(山東省科技進步一等獎),山東省人民政府,2009,5/12.
  • 榮譽稱號
    [1] 國家傑出青年基金獲得者
    [2] 國家“萬人計劃”科技創新領軍人才
    [3] 科技部中青年科技創新領軍人才
    [4] 教育部新世紀優秀人才支持計劃入選者
    [5] 山東省優秀研究生指導教師
    [6] 山東省有突出貢獻中青年專家專家
    [7] 山東省自然科學傑出青年基金獲得者
    [8] 孫越崎青年科技獎獲得者
  • 著作
    [1] 提高原油采收率潛力預測方法(專著),中國石油大學出版社,2007.9.
    [2] 油氣層滲流力學(國家級規劃教材),中國石油大學出版社,2009.4.
    [3] 熱力采油技術(高等學校教材),中國石油大學出版社,2013.5.
  • 論文
    發表論文200餘篇,近年代表性論文如下:
    [1] Zhang, W., Hou, J.*, Liu, Y., Zhou, K., Li, Z., & Du, Q. (2022). Determination of relative permeability curve under combined effect of polymer and surfactant. Journal of Petroleum Science and Engineering, 215, 110588.
    [2] Zhao, D., Hou, J.*, Sun, J., Shi, L., Du, Q., & Li, J. (2022). Interwell connectivity inversion method of steam flooding: Based on an analytical model and genetic algorithm. Journal of Petroleum Science and Engineering, 110641.
    [3] Ji, Y., Kneafsey, T. J., Hou, J.*, Zhao, J., Liu, C., Guo, T., ... & Bai, Y. (2022). Relative permeability of gas and water flow in hydrate-bearing porous media: A micro-scale study by lattice Boltzmann simulation. Fuel, 321, 124013.
    [4] Wu, D., Zhou, K., Zhao, F., Lu, X., An, Z., Liu, S., & Hou, J*. (2022). Determination of Permeability Contrast Limits for Applying Polymer Solutions and Viscoelastic Particle Suspensions in Heterogeneous Reservoirs. Energy & Fuels, 36(14), 7495-7506.
    [5] Zhai, M., Zhou, K., Sun, Z., Du, Q., Wei, Y., & Hou, J*. (2022). Study on the matching relationship between dispersed droplet size in O/W emulsion and reservoir permeability. International Journal of Multiphase Flow, 150, 104025.
    [6] Zhao, E., Hou, J.*, Ji, Y., Liu, Y., & Bai, Y. (2022). Energy recovery behavior of low-frequency electric heating assisted depressurization in Class 1 hydrate deposits. Fuel, 309, 122185.
    [7] Bai, Y., Hou, J.*, Liu, Y., Zhao, D., Bing, S., Xiao, W., & Zhao, W. (2022). Energy-consumption calculation and optimization method of integrated system of injection-reservoir-production in high water-cut reservoir. Energy, 239, 121961.
    [8] An, Z., Zhou, K., Hou, J.*, Wu, D., & Pan, Y. (2022). Accelerating reservoir production optimization by combining reservoir engineering method with particle swarm optimization algorithm. Journal of Petroleum Science and Engineering, 208, 109692.
    [9] Zhang, B., Jiang, R., Sun, B., Lu, N., Hou, J.*, Bai, Y., ... & Liu, Y. (2022). Establishment of the productivity prediction method of Class III gas hydrate developed by depressurization and horizontal well based on production performance and inflow relationship. Fuel, 308, 122006.
    [10] Zhai, M., Du, Q., Wu, G., Sun, J., Sha, Y., & Hou, J*. (2022). Potential of a new water-soluble agent for enhancing heavy oil recovery: A pore-scale investigation. Journal of Petroleum Science and Engineering, 208, 109646.
    [11] Zhang, W., Hou, J.*, Liu, Y., Du, Q., Cao, W., & Zhou, K. (2021). Study on the effect of polymer viscosity and Darcy velocity on relative permeability curves in polymer flooding. Journal of Petroleum Science and Engineering, 200, 108393.
    [12] Wang, H., Wei, B., Sun, Z., Du, Q., & Hou, J*. (2021). Microfluidic study of heavy oil emulsification on solid surface. Chemical Engineering Science, 246, 117009.
    [13] Ji, Y., Hou, J.*, Zhao, E., Liu, C., Guo, T., Liu, Y., ... & Bai, Y. (2021). Pore-scale study on methane hydrate formation and dissociation in a heterogeneous micromodel. Journal of Natural Gas Science and Engineering, 95, 104230.
    [14] Zhao, E., Hou, J.*, Du, Q., Liu, Y., Ji, Y., & Bai, Y. (2021). Numerical modeling of gas production from methane hydrate deposits using low-frequency electrical heating assisted depressurization method. Fuel, 290, 120075.
    [15] Zhao, E., Hou, J.*, Ji, Y., Liu, Y., & Bai, Y. (2021). Enhancing gas production from Class II hydrate deposits through depressurization combined with low-frequency electric heating under dual horizontal wells. Energy, 233, 121137.
    [16] Liu, Y., Hou, J.*, Chen, Z., Bai, Y., Su, H., Zhao, E., & Li, G. (2021). Enhancing hot water flooding in hydrate bearing layers through a novel staged production method. Energy, 217, 119319.
    [17] Wu, D., Zhou, K., Hou, J.*, An, Z., Zhai, M., & Liu, W. (2021). Review of experimental and simulation studies of enhanced oil recovery using viscoelastic particles. Journal of Dispersion Science and Technology, 42(7), 956-969.
    [18] Wei, B., Hou, J.*, Sukop, M. C., Du, Q., & Wang, H. (2020). Flow behaviors of emulsions in constricted capillaries: A lattice Boltzmann simulation study. Chemical Engineering Science, 227, 115925.
    [19] Wei, B., Hou, J.*, Sukop, M. C., & Du, Q. (2020). Enhancing oil recovery using an immiscible slug: Lattice Boltzmann simulation by three-phase pseudopotential model. Physics of Fluids, 32(9), 092105.
    [20] Liu, Y., Hou, J.*, Chen, Z., Su, H., Zhao, E., & Li, G. (2020). A novel natural gas hydrate recovery approach by delivering geothermal energy through dumpflooding. Energy Conversion and Management, 209, 112623.
    [21] Ji, Y., Hou, J.*, Zhao, E., Lu, N., Bai, Y., Zhou, K., & Liu, Y. (2020). Study on the effects of heterogeneous distribution of methane hydrate on permeability of porous media using low‐field NMR technique. Journal of Geophysical Research: Solid Earth, 125(2), e2019JB018572.
    [22] Bai, Y., Hou, J.*, Liu, Y., Lu, N., Zhao, E., & Ji, Y. (2020). Interbed patterns division and its effect on production performance for class I hydrate deposit with mudstone interbed. Energy, 211, 118666.
    [23] Wu, D., Zhou, K., Hou, J.*, An, Z., Zhai, M., & Liu, W. (2020). Experimental study on combining heterogeneous phase composite flooding and streamline adjustment to improve oil recovery in heterogeneous reservoirs. Journal of Petroleum Science and Engineering, 194, 107478.
    [24] Zhao, E., Hou, J.*, Liu, Y., Ji, Y., Liu, W., Lu, N., & Bai, Y. (2020). Enhanced gas production by forming artificial impermeable barriers from unconfined hydrate deposits in Shenhu area of South China sea. Energy, 213, 118826.
    [25] Liu, J., Yan, Y., Zhang, J., Xu, J., Chen, G., & Hou, J.* (2019). Theoretical investigation of storage capacity of hydrocarbon gas in sH hydrate. Chemical Physics, 525, 110393.
    [26] Zhou, K., Hou, J.*, Sun, Q., Guo, L., Du, Q., & Liu, Y. (2019). Study on the flow resistance of the dispersion system of deformable preformed particle gel in porous media using LBM-DEM-IMB method. Journal of Dispersion Science and Technology, 40(10), 1523-1530.
    [27] Liu, Y., Hou, J.*, Zhao, H., Liu, X., & Xia, Z. (2019). Numerical simulation of simultaneous exploitation of geothermal energy and natural gas hydrates by water injection into a geothermal heat exchange well. Renewable and Sustainable Energy Reviews, 109, 467-481.
    [28] Hou, J., Liu, J., Xu, J., Zhong, J., Yan, Y., & Zhang, J. (2019). Two-dimensional methane hydrate: Plum-pudding structure and sandwich structure. Chemical Physics Letters, 725, 38-44.
    [29] Du, Q. J., Pan, G. M., Hou, J.*, Guo, L. L., Wang, R. R., Xia, Z. Z., & Zhou, K. (2019). Study of the mechanisms of streamline-adjustment-assisted heterogeneous combination flooding for enhanced oil recovery for post-polymer-flooded reservoirs. Petroleum Science, 16(3), 606-618.
    [30] Wei, B., Hou, J.*, Sukop, M. C., & Liu, H. (2019). Pore scale study of amphiphilic fluids flow using the Lattice Boltzmann model. International Journal of Heat and Mass Transfer, 139, 725-735.
    [31] Zhou, P., Hou, J.*, Yan, Y., Wang, J., & Chen, W. (2019). Effect of aggregation and adsorption behavior on the flow resistance of surfactant fluid on smooth and rough surfaces: a many-body dissipative particle dynamics study. Langmuir, 35(24), 8110-8120.
    [32] Zhou, P., Wang, J., Wang, M., Hou, J.*, Lu, J. R., & Xu, H. (2019). Amino acid conformations control the morphological and chiral features of the self-assembled peptide nanostructures: Young investigators perspective. Journal of Colloid and Interface Science, 548, 244-254.
    [33] Liu, Y., Ma, X., & Hou, J.* (2019). Comparing the Effectiveness of SO2 with CO2 for Replacing Hydrocarbons from Nanopores. Energy & Fuels, 33(6), 5200-5207.
    [34] Liu, Y., Liu, X., Hou, J.*, Li, H. A., Liu, Y., & Chen, Z. (2019). Technical and economic feasibility of a novel heavy oil recovery method: Geothermal energy assisted heavy oil recovery. Energy, 181, 853-867.
    [35] Liu, Y., & Hou, J. (2019). Investigation on the potential relationships between geophysical properties and CH4 adsorption in a typical shale gas reservoir. Energy & Fuels, 33(9), 8354-8362.
    [36] Lu, N., Hou, J.*, Liu, Y., Barrufet, M. A., Bai, Y., Ji, Y., ... & Zhou, K. (2019). Revised inflow performance relationship for productivity prediction and energy evaluation based on stage characteristics of Class III methane hydrate deposits. Energy, 189, 116211.
    [37] Hou, J., Zhao, E., Liu, Y., Ji, Y., Lu, N., Liu, Y., ... & Bai, Y. (2019). Pressure-transient behavior in class III hydrate reservoirs. Energy, 170, 391-402.
    [38] 侯健,吳德君,韋貝,周康,鞏亮,曹緒龍,郭蘭磊.非均相複合驅非連續相滲流特征及提高驅油效率機製[J].中國石油大學學報(自然科學版),2019,43(05):128-135.
    [39] Ji, Y., Hou, J.*, Cui, G., Lu, N., Zhao, E., Liu, Y., & Du, Q. (2019). Experimental study on methane hydrate formation in a partially saturated sandstone using low-field NMR technique. Fuel, 251, 82-90.
    [40] Du, Q., Hou, J.*, Zhao, F., Zhou, K., Liu, W., & Liu, Y. (2019). A new organic fiber composite gel as a plugging agent for assisting CO2 huff and puff in water channeling reservoirs. Journal of Petroleum Science and Engineering, 179, 70-79.
    [41] Liu, Y., Hou, J., Liu, L., Zhou, K., Zhang, Y., Dai, T., ... & Cao, W. (2018). An inversion method of relative permeability curves in polymer flooding considering physical properties of polymer. SPE Journal, 23(05), 1929-1943.
    [42] Liu, Y., Bai, Y., Xia, Z., & Hou, J.* (2018). Parameter optimization of Depressurization− to− Hot− Water− Flooding in heterogeneous hydrate bearing layers based on the particle swarm optimization algorithm. Journal of Natural Gas Science and Engineering, 53, 403-415.
    [43] Zhou, P., Hou, J.*, Yan, Y., & Wang, J. (2018). The effect of surfactant adsorption on surface wettability and flow resistance in slit nanopore: A molecular dynamics study. Journal of colloid and interface science, 513, 379-388.
    [44] Wei, B., Huang, H., Hou, J.*, & Sukop, M. C. (2018). Study on the meniscus-induced motion of droplets and bubbles by a three-phase Lattice Boltzmann model. Chemical Engineering Science, 176, 35-49.
    [45] Lu, N., Hou, J.*, Liu, Y., Barrufet, M. A., Ji, Y., Xia, Z., & Xu, B. (2018). Stage analysis and production evaluation for class III gas hydrate deposit by depressurization. Energy, 165, 501-511.
    [46] Hou, J., Wei, B., Zhou, K., & Du, Q. (2018). Representing pore shapes by appropriate polygons in pore network models. Journal of Porous Media, 21(4).
    [47] Zhou, K., Hou, J.*, Sun, Q., Guo, L., Bing, S., Du, Q., & Yao, C. (2018). A study on particle suspension flow and permeability impairment in porous media using LBM–DEM–IMB simulation method. Transport in Porous Media, 124(3), 681-698.
    [48] Wei, B., Hou, J.*, Huang, H., Sukop, M. C., Liu, Y., & Zhou, K. (2018). Entry pressure for the rough capillary: Semi-analytical model, Lattice Boltzmann simulation. Journal of Hydrology, 562, 17-29.
    [49] Liu, Y., Hou, J.*, Zhao, H., Liu, X., & Xia, Z. (2018). A method to recover natural gas hydrates with geothermal energy conveyed by CO2. Energy, 144, 265-278.
    [50] Hou, J., Ji, Y., Zhou, K., Liu, Y., & Wei, B. (2018). Effect of hydrate on permeability in porous media: Pore-scale micro-simulation. International Journal of Heat and Mass Transfer, 126, 416-424.
  • 專利
    授權發明專利50餘項,近年代表性專利如下:
    [[1] 侯健; 紀雲開; 杜慶軍 等. Method for correcting permeability model of porous medium in dissociation process of gas hydrate, and method and system for determining permeability of hydrate-bearing porous medium, US202017015896.
    [2] 侯健; 趙二猛; 劉永革等. Method for enhancing gas recovery of natural gas hydrate reservoir, US201916600842.
    [3] 侯健; 趙二猛; 劉永革 等. Method for obtaining formation parameters of gas hydrate reservoir through well testing interpretation, US201916700239.
    [4] 侯健; 陸努; 劉永革 等. Method for calculating daily gas production rate of methane hydrate deposit based on inflow performance relationship formulas, US202016884263.
    [5] 侯健; 劉永革; 周康 等. Method used for exploiting natural gas hydrate reservoir, US201816215255.
    [6] 侯健; 周康; 劉永革 等. Method for simulation of microscopic flow of pre-crosslinked gel suspension liquid in porous medium, US201815989861.
    [7] 侯健; 趙二猛; 劉永革 等. 一種通過人工致密蓋層提高天然氣水合物藏采收率的方法, ZL201910496581.5.
    [8] 侯健; 劉永革; 周康 等. 一種水平井分段射孔開發非均質天然氣水合物藏的方法, ZL201810721969.6.
    [9] 侯健; 白雅潔; 劉永革 等. 一種分段水平井熱CO2吞吐開采非均質水合物藏的方法, ZL201710402535.5.
    [10] 侯健; 劉永革; 周鵬 等. 一種利用流體循環方式動用地熱能開采天然氣水合物藏的方法, ZL201710573395.8.
    [11] 侯健; 杜慶軍; 宮汝祥 等. 一種用於複合熱流體多井均質化注入的裝置及方法, ZL201610246870.6.
    [12] 侯健; 劉永革; 王文斌 等. 一種利用直井電加熱輔助降壓開采天然氣水合物藏的方法, ZL201610285738.6.
    [13] 侯健; 韋貝; 姚軍 等. 一種考慮粗糙表麵特征的岩石毛管力確定方法, ZL201510818606.0.
    [14] 侯健; 劉永革; 楊勇 等. 一種聚合物驅相對滲透率曲線的測量方法, ZL201610024682.9.
    [15] 侯健; 韋貝; 姚軍 等. 一種考慮凹凸性的岩石孔隙網絡模型的孔喉截麵構造方法, ZL201510818657.3.
  • 學術交流
    [1] Wu, D., Liu, Y., Lu, X., Hou, J., Zhou, K., Wei, B & Zheng, H. (2022, June). Study on Blockage and Fluid Diversion Behaviors of Polymer Microspheres. In SPE EuropEC-Europe Energy Conference featured at the 83rd EAGE Annual Conference & Exhibition. OnePetro.
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    [8] Ji, Y., Hou, J., Liu, Y., & Du, Q. (2020, August). Study on Formation and Dissociation of Methane Hydrate in Sandstone Using Low-Field Nuclear Magnetic Resonance Technology. In International Conference on Offshore Mechanics and Arctic Engineering (Vol. 84430, p. V011T11A017). American Society of Mechanical Engineers.
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    [10] Du, Q., Shi, L., Hou, J., Ji, Y., & Zhou, K. (2018, October). Inhibition of Gas Channeling by CO2 Foam in Ultra-high Watercut Reservoir: Experimental Investigation Using NMR. In SPE Russian Petroleum Technology Conference. OnePetro.
    [11] Zhou, K., Hou, J., Wu, D., & Du, Q. (2018, November). Study on flow diversion caused by deformable preformed particle gel. In Abu Dhabi International Petroleum Exhibition & Conference. OnePetro.
    [12] Wei, B., Hou, J., Wu, D., Wang, H., & Liu, H. (2018, December). Pore scale simulation of surfactant flooding by lattice Boltzmann method. In SPE International Heavy Oil Conference and Exhibition. OnePetro.
    [13] Wu, D., Zhou, K., An, Z., & Hou, J. (2018, December). Experimental study on the matching relationship between PPG size and reservoir heterogeneity. In SPE International Heavy Oil Conference and Exhibition. OnePetro.
    [14] Zhou, K., Hou, J., Ren, X., & Yu, B. (2017, April). Economic design of surfactant-polymer flooding under low oil price. In SPE Oil and Gas India Conference and Exhibition. OnePetro.
    [15] Lu, N., Hou, J., Liu, Y., Guo, L., Yuan, F., Wei, C., & Liu, Y. (2017, October). Optimization Chemical Flooding Methods to Enhance Oil Recovery of Strong Heterogeneity, High Temperature and High Salinity Reservoirs-Case Study of Shengli Oilfield. In SPE/IATMI Asia Pacific Oil & Gas Conference and Exhibition. OnePetro.
  • 個人風采
    油氣藏滲流力學與提高采收率團隊介紹:
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