◎研究方向
油氣井工程、海洋石油工程、多相流理論及應用，天然氣水合物開發：
（1）複雜條件下的井筒壓力控製
（2）鑽井水力學
（3）深水井控理論及應用
（4）深水井筒溫度壓力場預測技術
（5）深水測試及水合物防治
（6）欠平衡及控製壓力鑽井
（7）超臨界二氧化碳鑽井、壓裂過程中的相態控製
（8）智能完井優化設計
（9）海域天然氣水合物開發技術

◎學術兼職
（1）首屆國際水合物青年論壇主席
（2）SPE協會全球鑽井工程獎評委會委員
（3）SPE協會亞太油氣會議組委會委員
（4）科技部十三五重點研發計劃項目評審專家
（5）中國石油學會海洋工程工作部常務委員
（6）石油工程師協會（SPE）會員
（7）《Journal of Hydrodynamics》、《Geofluid》編委（SCI期刊）
（8）《Sim. Trans. of SCS 》（SCI期刊）客座主編
（9）《石油學報》、《天然氣工業》、《中國石油大學學報（自然科學版）》、《水動力學研究與進展》、《中國海上油氣》編委

◎主講課程
本科生課程：海洋鑽井工程、海洋油氣工程
研究生課程：深水鑽井工程、海洋油氣工程、深水油氣工程理論與技術進展

◎指導研究生
博士
2017級 潘少偉
2018級 張劍波、婁文強
2019級 仉誌、張洋洋、童仕坤、豆寧輝
2020級 劉徽

碩士
2014級 趙陽、潘少偉
2015級 張劍波、鄧智銘、胡偉鵬
2016級 於璟、鄭凱波、陳遠鵬
2017級 婁文強、劉徽、陳旺、王澤、劉漢橋、袁凱鵬
2018級 都凱、郭兵、張超、仉誌、童仕坤
2019級 弓正剛、郭宇堃、李迎超、範明、馬楠、孔慶文
2020級 裴繼昊、關立臣、楊賀民、陳剛、劉曉、李鵬飛

◎承擔科研課題
承擔省部級以上代表性課題14項
1.天然氣水合物鑽采井筒多相流動障礙形成機製與安全控製方法，國家自然科學基金重大項目課題，370萬元，2020年-2024年，負責人
2.海域天然氣水合物試采工程基礎及關鍵技術，中石油重大科技項目，4291萬元，2019年-2023年，負責人
3.海域天然氣水合物工程基礎理論研究室平台建設，中石油科技基礎條件平台建設項目，4444萬元，2019年-2021年，負責人
4.深水氣井測試環霧流條件下天然氣水合物流動障礙形成機製，國家自然科學基金麵上項目，60萬元，2020年-2023年，負責人
5.油氣井多相流動理論及應用，山東省傑出青年基金項目，60萬元，2017年-2020年，負責人
6.陵水25區塊開發井井筒流動保障技術研究，中海油外委課題，200.9萬，2020年-2022年，負責人
7.油氣井多相流動理論及應用，國家優青基金項目，130萬元，2017年-2019年，負責人
8.極地冰區鑽井防寒工藝技術研究，國家重點研發計劃，130萬元，2016年-2019年，負責人
9.深水鑽井非穩態多相流動規律與井筒壓力控製方法，國家973項目，755萬元，2015年-2019年，第二負責人
10.熱流體壓裂天然氣水合物儲層裂縫擴展基礎理論研究，山東省自然科學基金麵上項目，15萬元，2016年-2019年，負責人
11.智能井完井方式優化技術，國家863課題，240萬元，2013年-2016年，負責人
12.陵水17-2氣田開發井生產期間流動保障研究，中海油項目，60萬，2017年，負責人
13.頁岩氣儲層超臨界二氧化碳壓裂裂縫中支撐劑輸送機理研究，國家自然基金青年基金項目，25萬元，12年-15年，負責人
14.普光氣田高陡構造鑽井漏噴同存環空壓力控製機理研究，山東省自然科學基金項目，3萬元，2011年-2013年，負責人

◎獲獎情況
1.《海洋鑽井井筒安全壓力設計方法及關鍵技術》，海洋科技進步二等獎，海洋工程谘詢協會，2017年，1/15
2.《深部複雜壓力體係地層井筒壓力安全控製技術及應用》，中國安全生產協會第一屆安全科技進步二等獎，省部級，2019年，1/7
3.《多組分多相複雜流動理論及其在油氣井工程中的應用》，國家能源科技進步獎一等獎，2013年，3/15
4.《複雜鑽井工況下井筒壓力精確控製與工作液關鍵技術》，中國石油和化學工業聯合會科技進步一等獎，省部級，2016年，3/15；
5.《複雜壓力體係井筒安全高效構建關鍵技術及應用》，山東省科學技術進步二等獎，省部級，2019年3/9
6.《七組分井筒多相流動計算技術及應用》，山東省科技進步一等獎，省部級，2009年，4/11；
7.《複雜環境下油氣生產管柱與集輸管道安全保障關鍵技術及應用》，中國石油和化學工業聯合會科技進步一等獎，省部級，2018年，5/15

◎榮譽稱號
1.國家“萬人計劃”科技創新領軍人才
2.教育部長江學者獎勵計劃青年學者
3.國家優秀青年科學基金獲得者
4.山東省泰山學者特聘教授
5.孫越崎青年科技獎獲得者
6.山東省有突出貢獻的中青年科學家
7.山東省青年科技獎獲得者
8.山東省傑出青年科學基金獲得者

◎著作
出版專著2部，發表學術論文160餘篇，其中SCII收錄100餘篇
1.《深水氣井天然氣水合物防治理論與技術研究》，王誌遠、孫寶江、高永海著，科學出版社，2020
2.《Natural Gas Hydrate Management in Deepwater Gas Well》，Zhiyuan Wang • Baojiang Sun •Yonghai Gao，Springer，2020

◎論文
[1] Wang, Z., Tong, S., Wang, C., Zhang, J., Fu, W., & Sun, B. (2020). Hydrate deposition prediction model for deep-water gas wells under shut-in conditions. Fuel, 275, 117944.
[2] Wang, Z., Liu, H., Zhang, Z., Sun, B., Zhang, J., & Lou, W. (2020). Research on the effects of liquid viscosity on droplet size in vertical gas–liquid annular flows. Chemical Engineering Science, 115621.
[3] Wang Z , Lou W , Sun B , et al. A model for predicting bubble velocity in yield stress fluid at low Reynolds number[J]. Chemical Engineering Science, 2019, 201:325-338.
[4] Wang Z, Yu J, Zhang J, et al. Improved thermal model considering hydrate formation and deposition in gas-dominated systems with free water[J]. Fuel, 2019, 236: 870-879.
[5] Wang Z, Zhao Y, Zhang J, et al. Quantitatively Assessing Hydrate-Blockage Development During Deepwater-Gas-Well Testing[J]. SPE Journal, 2018, 23(04): 1,166-1,183.
[6] Wang Z, Liao Y, Zhang W, et al. Coupled temperature field model of gas-hydrate formation for thermal fluid fracturing[J]. Applied Thermal Engineering, 2018, 133: 160-169.
[7] Wang Z, Zhao Y, Zhang J, et al. Flow assurance during deepwater gas well testing: Hydrate blockage prediction and prevention[J]. Journal of Petroleum Science and Engineering, 2018, 163: 211-216.
[8] Wang Z, Zhang J, Sun B, et al. A new hydrate deposition prediction model for gas-dominated systems with free water[J]. Chemical Engineering Science, 2017, 163: 145-154.
[9] Wang Z, Zhang J, Chen L, et al. Modeling of hydrate layer growth in horizontal gas-dominated pipelines with free water[J]. Journal of Natural Gas Science & Engineering, 2017, 50:364–373.
[10] Wang Z, Sun B, Sun X. Calculation of temperature in fracture for carbon dioxide fracturing[J]. SPE Journal, 2016, 21(05): 1491-1500.
[11] Wang Z, Zhao Y, Sun B, et al. Modeling of hydrate blockage in gas-dominated systems[J]. Energy & Fuels, 2016, 30(6): 4653-4666.
[12] Wang Z, Sun B, Sun X, et al. Phase state variations for supercritical carbon dioxide drilling[J]. Greenhouse Gases: Science and Technology, 2016, 6(1): 83-93.
[13] Wang Z, Sun B, Yan L. Improved density correlation for supercritical CO2[J]. Chemical Engineering & Technology, 2015, 38(1): 75-84.
[14] WANG Z, SUN B, WANG X, et al. Prediction of natural gas hydrate formation region in wellbore during deep-water gas well testing[J]. Journal of Hydrodynamics, Ser. B, 2014, 26(4): 568-576.
[15] Wang Z, Sun B, Wang J, et al. Experimental study on the friction coefficient of supercritical carbon dioxide in pipes[J]. International Journal of Greenhouse Gas Control, 2014, 25(6): 151-161.
[16] WANG Z, SUN B. Deepwater gas kick simulation with consideration of the gas hydrate phase transition[J]. Journal of Hydrodynamics, Ser. B, 2014, 26(1): 94-103.
[17] Wang Z, Sun B, Ke K. Pre-Spud Mud Loss Flow Rate in Steeply Folded Structures[J]. Oil & Gas Science & Technology, 2013, 69(7):1269-1281.
[18] Wang Z, Sun B. Annular multiphase flow behavior during deep water drilling and the effect of hydrate phase transition[J]. Petroleum Science, 2009, 6(1): 57-63.
[19] He, H., Sun, B, Wang, Z, Liu, Y., & Sun, X. (2020). A constitutive model for predicting the solubility of gases in water at high temperature and pressure. Journal of Petroleum Science and Engineering, 107337.
[20] Zhang, J., Wang, Z., Duan, W., Fu, W., Sun, B., Sun, J., & Tong, S. (2020). Real-Time Estimation and Management of Hydrate Plugging Risk During Deepwater Gas Well Testing. SPE Journal.
[21] Sun, B., Zhang, Z., Wang, Z., Pan, S., Wang, Z., & Chen, W. (2020). Parameter Prediction Method for Submarine Cuttings Piles in Offshore Drilling. SPE Journal.
[22] Fang, T., Zhang, Y., Yan, Y., Wang, Z., & Zhang, J. (2020). Molecular insight into the oil extraction and transport in CO2 flooding with reservoir depressurization. International Journal of Heat and Mass Transfer, 148, 119051.
[23] Chenwei Liu, Zhiyuan Wang, Jinlin Tian, et al. (2020). Fundamental investigation of the adhesion strength between cyclopentane hydrate deposition and solid surface materials. Chemical Engineering Science, 217, 115524.
[24] Deng, X., Pan, S., Zhang, J., Wang, Z., & Jiang, Z. (2020). Numerical investigation on abnormally elevated pressure in laboratory-scale porous media caused by depressurized hydrate dissociation. Fuel, 271, 117679.
[25] Lou, W., Wang, Z., Pan, S., Sun, B., Zhang, J., & Chen, W. (2020). Prediction model and energy dissipation analysis of Taylor bubble rise velocity in yield stress fluid. Chemical Engineering Journal, 125261.
[26] Liao, Y., Sun, X., Sun, B., Wang, Z., Zhang, J., & Lou, W. (2020). Wellhead backpressure control strategies and outflow response characteristics for gas kick during managed pressure drilling. Journal of Natural Gas Science and Engineering, 75, 103164.
[27] Fu, W., Wang, Z., Zhang, J., & Sun, B. (2020). Methane hydrate formation in a water-continuous vertical flow loop with xanthan gum. Fuel, 265, 116963.
[28] Deng, X., Feng, J., Pan, S., Wang, Z., Zhang, J., & Chen, W. (2020). An improved model for the migration of fluids caused by hydrate dissociation in porous media. Journal of Petroleum Science and Engineering, 106876.
[29] Sun, B., Pan, S., Zhang, J., Zhao, X., Zhao, Y., & Wang, Z. (2019). A Dynamic Model for Predicting the Geometry of Bubble Entrapped in Yield Stress Fluid. Chemical Engineering Journal, 123569.
[30] Zhang, L., Wang, Z., Du, K., Xiao, B., & Chen, W. (2019). A new analytical model of wellbore strengthening for fracture network loss of drilling fluid considering fracture roughness. Journal of Natural Gas Science and Engineering, 103093.
[31] Wang J, Sun B, Chen W, et al. Calculation model of unsteady temperature–pressure fields in wellbores and fractures of supercritical CO2 fracturing[J]. Fuel, 2019, 253: 1168-1183.
[32] Sun B, Fu W, Wang Z, et al. Characterizing the rheology of methane hydrate slurry in a horizontal water-continuous system[J]. SPE Journal, 2019.
[33] Sun X, Liao Y, Wang Z, et al. Geothermal exploitation by circulating supercritical CO2 in a closed horizontal wellbore[J]. Fuel, 2019, 254: 115566.
[34] Fu W, Wang Z, Zhang J, et al. Investigation of rheological properties of methane hydrate slurry with carboxmethylcellulose[J]. Journal of Petroleum Science and Engineering, 2019: 106504.
[35] Liao Y, Sun X, Sun B, et al. Transient gas–liquid–solid flow model with heat and mass transfer for hydrate reservoir drilling[J]. International Journal of Heat and Mass Transfer, 2019, 141: 476-486.
[36] Liao Y, Sun X, Sun B, et al. Coupled thermal model for geothermal exploitation via recycling of supercritical CO2 in a fracture–wells system[J]. Applied Thermal Engineering, 2019: 113890. [19] Zhang J, Wang Z, Liu S, et al. Prediction of hydrate deposition in pipelines to improve gas transportation efficiency and safety[J]. Applied Energy, 2019, 253: 113521.
[37] Zhang J, Wang Z, Sun B, et al. An integrated prediction model of hydrate blockage formation in deep-water gas wells[J]. International Journal of Heat and Mass Transfer, 2019, 140: 187-202.
[38] Deng X, Pan S, Wang Z, et al. Application of the Darcy-Stefan model to investigate the thawing subsidence around the wellbore in the permafrost region[J]. Applied Thermal Engineering, 2019, 156: 392-401.
[39] Fu W, Wang Z, Yue X, et al. Experimental Study of Methane Hydrate Formation in Water-continuous Flow Loop[J]. Energy & Fuels, 2019.
[40] Fu W, Wang Z, Duan W, et al. Characterizing methane hydrate formation in the non-Newtonian fluid flowing system[J]. Fuel, 2019, 253: 474-487.
[41] Sun B, Yang C, Wang Z, et al. Methodology for pressure drop of bubbly flow based on energy dissipation[J]. Journal of Petroleum Science and Engineering, 2019, 177: 432-441.
[42] Fu W, Wang Z, Sun B, et al. Multiple controlling factors for methane hydrate formation in water-continuous system[J]. International Journal of Heat and Mass Transfer, 2019, 131: 757-771.
[43] Wang J, Wang Z, Sun B, et al. Optimization design of hydraulic parameters for supercritical CO2 fracturing in unconventional gas reservoir[J]. Fuel, 2019, 235: 795-809.
[44] Sun B, Zhang Z, Wang Z, et al. Interfacial friction factor prediction in vertical annular flow based on the interface roughness[J]. Chemical Engineering & Technology, 2018, 41(9): 1833-1841.
[45] Wang M, Wang J, Fang T, Yang Y, Wang Z, et al. Shape Transition of Water-in-CO2 Reverse Micelles Controlled by Surfactant Midpiece[J]. Physical Chemistry Chemical Physics, 2018, 20(22): 15535-15542.
[46] Sun B, Wang J, Wang Z, et al. Calculation of proppant-carrying flow in supercritical carbon dioxide fracturing fluid[J]. Journal of Petroleum Science and Engineering, 2018, 166: 420-432.
[47] Sun X, Wang Z, Sun B, et al. Research on hydrate formation rules in the formations for liquid CO2 fracturing[J]. Journal of Natural Gas Science and Engineering, 2016, 33: 1390-1401.
[48] Wang N, Sun B, Wang Z, et al. Numerical simulation of two phase flow in wellbores by means of drift flux model and pressure based method[J]. Journal of Natural Gas Science and Engineering, 2016, 36: 811-823.
[49] Chenwei Liu, Zhiyuan Wang, Jinlin Tian, et al. (2020). Fundamental investigation of the adhesion strength between cyclopentane hydrate deposition and solid surface materials. Chemical Engineering Science, 217, 115524.
[50] Lou, W., Wang, Z., Pan, S., Sun, B., Zhang, J., & Chen, W. (2020). Prediction model and energy dissipation analysis of Taylor bubble rise velocity in yield stress fluid. Chemical Engineering Journal, 125261.
[51] Jianbo Zhang，Zhiyuan Wang，Wenguang Duan，et al. (2020). Real-Time Estimation and Management of Hydrate Plugging Risk During Deepwater Gas Well Testing. SPE Journal,
[52] Fu, W., Wang, Z., Chen, L., & Sun, B. (2020). Experimental Investigation of Methane Hydrate Formation in the Carboxmethylcellulose (CMC) Aqueous Solution. SPE Journal.
[53] Fu, W., Wang, Z., Sun, B., Xu, J., Chen, L., & Wang, X. (2020). Rheological Properties of Methane Hydrate Slurry in the Presence of Xanthan Gum. SPE Journal.
[54] Fu, W., Wang, Z., Zhang, J., & Sun, B. (2020). Methane hydrate formation in a water-continuous vertical flow loop with xanthan gum. Fuel, 265, 116963.
[55] Zhang Z, Wang Z, Gao Y, et al. Experimental study on the effect of surfactants on the characteristics of gas carrying liquid in vertical churn and annular flows[J]. Journal of Petroleum Science and Engineering, 2019, 180: 347-356.
[56] Zhang Z, Wang Z, Liu H, et al. Experimental study on entrained droplets in vertical two-phase churn and annular flows[J]. International Journal of Heat and Mass Transfer, 2019, 138: 1346-1358.
[57] Zhang Z, Wang Z, Liu H, et al. Experimental study on bubble and droplet entrainment in vertical churn and annular flows and their relationship[J]. Chemical Engineering Science, 2019, 206: 387-400.
[58] Zhang S, Wang Z, Sun B, et al. Pattern transition of a gas–liquid flow with zero liquid superficial velocity in a vertical tube[J]. International Journal of Multiphase Flow, 2019, 118: 270-282.
[59] Sun X, Wang Z, Liao Y, et al. Geothermal energy production utilizing a U-shaped well in combination with supercritical CO2 circulation[J]. Applied Thermal Engineering, 2019, 151: 523-535.
[60] Fu W, Wang Z, Sun B, et al. A mass transfer model for hydrate formation in bubbly flow considering bubble-bubble interactions and bubble-hydrate particle interactions[J]. International Journal of Heat and Mass Transfer, 2018, 127: 611-621.
[61] Sun X, Wang Z, Sun B, et al. Modeling of dynamic hydrate shell growth on bubble surface considering multiple factor interactions[J]. Chemical Engineering Journal, 2018, 331: 221-233.
[62] Wang X, Wang Z, Deng X, et al. Coupled thermal model of wellbore and permafrost in Arctic regions[J]. Applied Thermal Engineering, 2017, 123: 1291-1299.
[63] Wang J, Wang Z, Sun B. Improved equation of CO2 Joule–Thomson coefficient[J]. Journal of CO2 Utilization, 2017, 19: 296-307.
[64] He, H., Sun, B., Wang, Z., Liu, Y., & Sun, X. (2020). A constitutive model for predicting the solubility of gases in water at high temperature and pressure. Journal of Petroleum Science and Engineering, 107337.
[65] Sun, B., Zhang, Z., Wang, Z., Pan, S., Wang, Z., & Chen, W. (2020). Parameter Prediction Method for Submarine Cuttings Piles in Offshore Drilling. SPE Journal.
[66] Gao Y, Chen Y, Wang Z, et al. Experimental study on heat transfer in hydrate-bearing reservoirs during drilling processes[J]. Ocean Engineering, 2019, 183: 262-269.
[67] Liu Z, Sun B, Wang Z, et al. New Mass-Transfer Model for Predicting Hydrate Film Thickness at the Gas–Liquid Interface under Different Thermodynamics–Hydrodynamics-Saturation Conditions[J]. The Journal of Physical Chemistry C, 2019, 123(34): 20838-20852.
[68] Sun B, Liu Z, Wang Z, et al. Experimental and modeling investigations into hydrate shell growth on suspended bubbles considering pore updating and surface collapse[J]. Chemical Engineering Science, 2019.
[69] Wang X, Sun B, Wang Z, et al. Coupled heat and mass transfer model of gas migration during well cementing through a hydrate layer in deep-water regions[J]. Applied Thermal Engineering, 2019: 114383.
[70] Zhao Y, Liu S, Wang Z, et al. An adaptive pattern recognition method for early diagnosis of drillstring washout based on dynamic hydraulic model[J]. Journal of Natural Gas Science and Engineering, 2019, 70: 102947.
[71] Zhang Z, Sun B, Wang Z, et al. Whole wellbore liquid loading recognition model for gas wells[J]. Journal of Natural Gas Science and Engineering, 2018, 60: 153-163.
[72] Sun X, Sun B, Wang Z, et al. A hydrate shell growth model in bubble flow of water-dominated system considering intrinsic kinetics, mass and heat transfer mechanisms[J]. International Journal of Heat and Mass Transfer, 2018, 117: 940-950.
[73] Sun B, Wang X, Wang Z, et al. Transient temperature calculation method for deep-water cementing based on hydration kinetics model[J]. Applied Thermal Engineering, 2018, 129: 1426-1434.
[74] Sun B, Sun X, Wang Z, et al. Effects of phase transition on gas kick migration in deepwater horizontal drilling[J]. Journal of Natural Gas Science and Engineering, 2017, 46: 710-729.
[75] Wang J, Sun B, Wang Z, et al. Study on filtration patterns of supercritical CO2 fracturing in unconventional natural gas reservoirs[J]. Greenhouse Gases Science & Technology, 2017, 7(6): 1126-1140.
[76] Sun X, Sun B, Wang Z, et al. A new model for hydrodynamics and mass transfer of hydrated bubble rising in deep water[J]. Chemical Engineering Science, 2017, 173: 168-178.
[77] Sun B, Guo Y, Wang Z, et al. Experimental study on the drag coefficient of single bubbles rising in static non-Newtonian fluids in wellbore[J]. Journal of Natural Gas Science and Engineering, 2015, 26: 867-872.
[78] Hou L, Sun B, Wang Z, et al. Experimental study of particle settling in supercritical carbon dioxide[J]. The Journal of Supercritical Fluids, 2015, 100: 121-128.
[79] SUN B, GONG P, WANG Z. Simulation of gas kick with high H2S content in deep well[J]. Journal of Hydrodynamics, Ser. B, 2013, 25(2): 264-273.
[80] Wang, X., Shen, H., Sun, B., Wang, Z., Gao, Y., Li, H., & Pang, X. (2020). Mechanism of gas migration through microstructure of cemented annulus in deep-water environment. Journal of Natural Gas Science and Engineering, 103316.
[81] Yin, B., Zhang, X., Sun, B., Wang, Z., Gong, P., & Huang, M. Evaluation Method for Probability of Blowout after the Failure of Offshore Well Killing. Indian Journal of Geo Marine Sciences, 2020. 49(02):249-259
[82] Wang X, Sun B, Gao Y, et al. Numerical simulation of the stability of hydrate layer during well cementing in deep-water region[J]. Journal of Petroleum Science and Engineering, 2019, 176: 893-905.
[83] Sun B, Fu W, Wang N, et al. Multiphase flow modeling of gas intrusion in oil-based drilling mud[J]. Journal of Petroleum Science and Engineering, 2019, 174: 1142-1151.
[84] Jin-Tang W , Bao-Jiang S , Hao L , et al. Numerical simulation of cementing displacement interface stability of extended reach wells[J]. Journal of Hydrodynamics, 2018, 30(3):420-432.
[85] Gao Y, Chen Y, Zhao X, et al. Risk analysis on the blowout in deepwater drilling when encountering hydrate-bearing reservoir[J]. Ocean Engineering, 2018, 170: 1-5.
[86] Gao Y, Sun X, Zhao T, et al. Study on the migration of gas kicks in undulating sections of horizontal wells[J]. International Journal of Heat and Mass Transfer, 2018, 127: 1161-1167.
[87] Wang X, Sun B, Luo P, et al. Transient temperature and pressure calculation model of a wellbore for dual gradient drilling[J]. Journal of Hydrodynamics, 2018, 30(4): 701-714.
[88] Sun X, Sun B, Zhang S, et al. A new pattern recognition model for gas kick diagnosis in deepwater drilling[J]. Journal of Petroleum Science and Engineering, 2018, 167: 418-425.
[89] Sun X, Sun B, Gao Y, et al. A model of multiphase flow dynamics considering the hydrated bubble behaviors and its application to deepwater kick simulation[J]. Journal of Energy Resources Technology, 2018, 140(8): 082004.
[90] Wang N, Sun B, Gong P, et al. Improved Void Fraction Correlation for Two‐Phase Flow in Large‐Diameter Annuli[J]. Chemical Engineering & Technology, 2017, 40(4): 745-754.
[91] Wang N, Wang J, Sun B, et al. Study of transient responses in the APWD measurements during gas influx[J]. Journal of Natural Gas Science and Engineering, 2016, 35: 522-531.
[92] Sun, X., Xia, A., Sun, B., Liao, Y., Wang, Z., & Gao, Y. (2019). Research on the heat and mass transfer mechanisms for growth of hydrate shell from gas bubbles. The Canadian Journal of Chemical Engineering, 97(6), 1953-1960.
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◎專利
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