部分代表论著: 1.祝效华,刘伟吉. 钻井岩石破碎学[M].科学出版社,2022.(学术专著) 2.Liu W, Zhang Y, Zhu X, et al. The influence of pore characteristics on rock fragmentation mechanism by high voltage electric pulses[J]. Plasma Science and Technology, 2022 3. Liu W, Luo Y, Zhu X, et al. The ductile-brittle failure mode transition of hard brittle rock cutting—new insights from numerical simulation[J]. Geomechanics and Geophysics for Geo-Energy and Geo-Resources,2022, 8(4): 1-24. 4.Liu W, Zhu X*, Lv Y, Hua Tong. On the mechanism of thermally induced micro-cracking assisted rock cutting in hard formation[J]. Journal of Petroleum Science and Engineering, 2021, 196: 311-319. 5.Liu W, Qian X, Li T, et al. Investigation of the tool-rock interaction using Drucker-Prager failure criterion[J]. Journal of Petroleum Science and Engineering, 2019, 173: 269-278. 6.Liu W, Zhu X*, Jing J. The analysis of ductile-brittle failure mode transition in rock cutting[J]. Journal of Petroleum Science and Engineering, 2018, 163: 311-319. 7.Zhu X, Luo Y, Liu W*, et al. Numerical electric breakdown model of heterogeneous granite for electro-pulse-boring[J]. International Journal of Rock Mechanics and Mining Sciences, 2022, 154: 105128. 8.Zhu X, Chen M, Liu W*, et al. The Fragmentation Mechanism of Heterogeneous Granite by High-Voltage Electrical Pulses[J]. Rock Mechanics and Rock Engineering, 2022, 55: 4351–4372. 9.Zhu X, Luo Y, Liu W*, et al. Rock cutting mechanism of special-shaped PDC cutter in heterogeneous granite formation[J]. Journal of Petroleum Science and Engineering, 2022,210: 110020. 10.Zhu X*, Liu W, Jiang J. Research regarding coal-bed wellbore stability based on a discrete element model[J]. Petroleum Science, 2014, 11(4): 526-531. 11.Zhu X* and Liu W. Research on the effect of drill string impact on wellbore stability. Journal of Petroleum Science and Engineering, 2013, 109: 217-229. 12.Zhu X*, Luo Y, Liu W. On the rock-breaking mechanism of plasma channel drilling technology[J]. Journal of Petroleum Science and Engineering, 2020, 194, 107356. IF=5.1 13.Zhu X, Luo Y*, Liu W. On the Mechanism of High?Voltage Pulsed Fragmentation from Electrical Breakdown Process[J]. Rock Mechanics and Rock Engineering, 2021, 1-24. IF=6.5 14.刘伟吉,张有建,罗云旭,祝效华. 岩石内部高压电脉冲等离子体通道生成机理研究[J].石油学报,2023,卓越期刊 15.刘伟吉,向畅,谭宾等.局部高温诱导致裂非均质花岗岩机理研究[J].工程力学,2022,卓越期刊 16.刘伟吉,胡海,祝效华等.围压条件下电脉冲破碎干热岩机理研究[J].天然气工业,2022,卓越期刊 17.刘伟吉,阳飞龙,董洪铎等.异形PDC齿混合切削破碎花岗岩特性研究[J].工程力学,2022,卓越期刊 18.刘伟吉,王燕飞,郭天阳,祝效华等.单齿切削破碎非均质花岗岩微宏观机理研究[J].工程力学,2021,卓越期刊 19.祝效华,刘伟吉. 单齿高频扭转冲击切削的破岩及提速机理研究[J].石油学报,2017,卓越期刊 20.祝效华, 刘伟吉. 旋冲钻井技术的破岩及提速机理[J].石油学报, 2018,卓越期刊 21.祝效华, 罗云旭, 刘伟吉,等. 等离子体电脉冲钻井破岩机理的电击穿实验与数值模拟方法[J].石油学报, 2020,卓越期刊 部分发明专利: 1.一种基于塑性耗能比的岩石破碎效率评价方法,发明专利(专利技术许可,29.8万) 2.一种用于电脉冲-机械复合破岩钻头的钻井实验装置,发明专利 3.一种用于深部难钻地层的电脉冲-机械复合破岩钻头,发明专利 4.一种用于电脉冲-机械复合破岩钻头与钻具间的电缆连接装置,发明专利 5.一种热致裂辅助钻头高效破岩钻井提速系统,发明专利 6.一种基于反馈控制的预击穿-储能放电破岩系统,发明专利 7.一种用于电脉冲破岩的磁开关脉冲发生器拓扑结构,发明专利 8.一种钕磁铁式水力振荡器,发明专利 9.一种适用于深部硬地层的强动力复合冲击器,发明专利 10.一种切削破岩实验装置及其实验方法,发明专利 11.一种基于高压电脉冲液电效应的冲击提速钻具,发明专利 12.一种三维井筒系统的提速评价方法,发明专利 13.一种用于减少井壁掉块导致钻头埋钻发生几率的方法,发明专利 14.一种安装于钻头内部的三轴振动测量装置,发明专利 |