◎研究方向
(1) 井筒与储层耦合多相流动理论
(2) 流体相变传质传热
(3) 深水井控技术

◎主讲课程
必修课 海洋钻井技术 石油工程专业

◎获奖情况
1. 深水深部高温高压油气藏安全钻井多相流压力控制技术及工业化应用，山东省研究生优秀科技创新成果一等奖，省级，2019，排名第1；

◎荣誉称号
2019年，学术十杰

◎论文
[1] Sun, X., Wang, Z., Sun, B., Chen, L., Zhang, J., 2018. Modeling of dynamic hydrate shell growth on bubble surface considering multiple factor interactions. Chemical Engineering Journal. 331, 221-233. (SCI检索)
[2] Sun, X., Sun, B., Wang, Z., Chen, L., Gao, Y., 2017. A new model for hydrodynamics and mass transfer of hydrated bubble rising in deep water. Chemical Engineering Science. 173, 168-178. (SCI检索)
[3] Sun, X., Sun, B., Wang, Z., Chen, L., Gao, Y., 2018. A hydrate shell growth model in bubble flow of water-dominated system considering intrinsic kinetics, mass and heat transfer mechanisms. International Journal of Heat and Mass Transfer. 117, 940–950. (SCI检索)
[4] Sun, X., Wang, Z., Liao, Y., Sun, B. (2019). Geothermal energy production utilizing a U-shaped well in combination with supercritical CO2 circulation. Applied Thermal Engineering, 151, 523-535. (SCI检索)
[5] Sun, X., Liao, Y., Wang, Z., & Sun, B. (2019). Geothermal exploitation by circulating supercritical CO2 in a closed horizontal wellbore. Fuel, 254, 115566. (SCI检索)
[6] Sun, B., Sun, X., Wang, Z., Chen, Y., 2017. Effects of phase transition on gas kick migration in deep water horizontal drilling. Journal of Natural Gas Science & Engineering. 46: 710-729. (SCI检索)
[7] Sun, X., Wang, Z., Sun, B., Wang, W., 2016. Research on hydrate formation rules in the formations for liquid CO2 fracturing. Journal of Natural Gas Science & Engineering. 33, 1390-1401. (SCI检索)
[8] Sun, X., Sun, B., Zhang, S., Wang, Z., Gao, Y., & Li, H. (2018). A new pattern recognition model for gas kick diagnosis in deepwater drilling. Journal of Petroleum Science and Engineering, 167, 418-425. (SCI检索)
[9] Sun, X., Sun, B., Gao, Y., & Wang, Z. (2018). A model of multiphase flow dynamics considering the hydrated bubble behaviors and its application to deepwater kick simulation. Journal of Energy Resources Technology, 140(8), 082004. (SCI检索)
[10] 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. (SCI检索)
[11] Gao, Y., Sun, X., Zhao, T., Wang, Z. (2018). Study on the migration of gas kicks in undulating sections of horizontal wells. International Journal of Heat and Mass Transfer, 127, 1161-1167. (SCI检索)
[12] Liao, Y., Sun, X., Sun, B. (2019). Transient gas–liquid–solid flow model with heat and mass transfer for hydrate reservoir drilling. International Journal of Heat and Mass Transfer, 141, 476-486. (SCI检索)
[13] Liao, Y., Sun, X., Sun, B., Xu, J., Huang, D., & Wang, Z. (2019). Coupled thermal model for geothermal exploitation via recycling of supercritical CO2 in a fracture–wells system. Applied Thermal Engineering, 113890. (SCI检索)
[14] Sun, X., Sun, B., Wang, Z. Wellbore Dynamics of Kick Evolution Considering Hydrate Phase Transition on Gas Bubbles Surface During Deepwater Drilling. Presented in ASME 2017, International Conference on Ocean, Offshore and Arctic Engineering, OMAE2017-61125. Trondheim, Norway, June 25-30, 2017. (EI检索)
[15] Sun, X., Sun, B., Gao, Y., Wang, Z., Liao, Y., Yu, X. Transient Fully Coupled Hydrodynamic-Hydrate Model for Deepwater Kick Simulation. Presented in the Offshore Technology Conference Asia, OTC-28342-MS. Kuala Lumpur, Malaysia, 20-23 March, 2018 (EI检索)
[16] Sun, X., Sun, B., Gao., Wang, Z. The behaviors of gas bubble migration and pressure build-up during the dynamic shut-in procedure in deep water drilling. Presented in ASME 2018, International Conference on Ocean, Offshore and Arctic Engineering, OMAE 2018-77920. Madrid, Spain, June 17-22, 2018. (EI检索)
[17] Wang Z, Sun B, Sun X, 2016. Calculation of Temperature in Fracture for Carbon Dioxide Fracturing. SPE Journal, 21(5): 1-10. (SCI检索)
[18] Wang, Z., Sun, B., Sun, X., Li, H., Wang, J., 2016. Phase state variations for supercritical carbon dioxide drilling. Greenhouse Gases Science & Technology, 6(1):83-93. (SCI检索)
[19] 孙小辉，孙宝江，王志远，2015. 超临界CO2压裂裂缝温度场模型. 石油学报. 36 (12): 1586-1592. (EI检索)
[20] 孙宝江, 孙小辉, 王志远, 王金堂, 刘书杰, 夏强, 蔡德军, 2016. 超临界CO2钻井井筒内流动参数变化规律. 中国石油大学学报(自然科学版), 40 (3): 1-8. (EI检索)
[21] 孙小辉, 孙宝江, 王志远, 王金堂, 2015. 超临界CO2钻井井筒水合物形成区域预测. 石油钻探技术. 43 (6): 13-19. (EI检索)
[22] 孙小辉, 孙宝江, 王志远, 王金堂，王宁. 超临界二氧化碳压裂裂缝内温度场计算方法. 全国水动力学研讨会. 2014, 385-392. (EI检索)

◎专利
[1] Sun, B., Sun, X., Wang, Z., Zhou, J., 2017. Kick information identification apparatus and method assisted for wellbore pressure control during horizontal drilling. US 9631444 B1. 美国发明专利，排名第2
[2] 孙宝江, 孙小辉, 王志远, 周建良, 2017. 测量单元、溢流信息识别设备及方法. CN 106401571 A，排名第2
[3] 孙宝江, 王宁, 王志远, 公培斌, 陈永明, 孙小辉, 张振楠，2013. 井喷无法关井情况下的地层压力确定方法. CN103244108A，排名第6

◎学术交流
2018.9-2019.9 美国加州大学伯克利分校和劳伦斯伯克利国家实验室联合培养