分享郑明明Zheng Mingming副教授 / 硕士生导师 扫一扫在手机打开此页面所在单位：环境与土木工程学院，地质工程（钻掘工程） 研究领域：地质工程、地下空间工程 职????务： mingming_zheng513@163.com84078874个人简介 Introduction发表论文 Paper Publications发明专利 Patents科研项目 Research Projects 基本信息 Introduction? ? ? ?郑明明，男，江苏连云港人，工学博士，副教授，硕士生导师。2016年毕业于中国地质大学（武汉），曾为美国德州农工大学（TAMUC）访问学者、中南大学助理研究员，现为成都理工大学地质工程专业教师。 ? ? ? ?研究领域为地质工程、地下空间工程。主要包括钻井/孔相关的井壁力学稳定，储层基础物性、井壁稳定评价、涉及传质传热相变的钻、固井与开采过程中储层物性响应；地下空间工程结构支护与抗渗，新型支护结构与材料，超深地下工程长期抗渗评价与措施。解决非常规能源钻采、地下工程掘进支护的孔/洞壁力学稳定关键科学技术难题。 ? ? ? ?主要成果包括主持与主研国家重点研发计划、国家自然科学基金、教育部重点实验室开放基金等科研项目10余项。以第一和通讯作者发表学术论文20余篇（SCI/EI 15篇），申请发明专利10项，主编英文专著1部，参加国际学术会议8次。获GEESD 2020最佳学术海报奖，获中国地质学会地质类工程专业优秀本科毕业设计指导教师。 荣誉称号 Academic Awards and Honors 工作经历 Work Experience2016.09- 2017.05至今， 中南大学地球科学与信息物理学院， 助理研究员 2015.05- 2016.05至今， 美国德州农工大学康默思分校土木工程系， 访问学者 2017.07- 2020.02至今， 成都理工大学， 讲师 2020.03- 2020.05至今， 成都理工大学， 副教授 个人新闻更多友情链接更多教育经历Education Background 2007.09-2011.06，中国地质大学（武汉），工程学院勘查技术与工程专业，本科 2011.09-2016.06，中国地质大学（武汉），工程学院地质工程专业（直博），博士研究生 发表论文Paper Publications[1]. Jingjing Wu, Shaohe Zhang, Han Cao, Mingming Zheng*, et al..Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir,Journal of Natural Gas Science and Engineering, 2020 ,75 (-):103159 ( SCIE收录; EI收录; )[2]. Mingming Zheng, Tianle Liu, Guosheng Jiang, et al..Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico,Journal of Petroleum Science and Engineering, 2020 ,187 (-):106832 ( SCIE收录; EI收录; )[3]. Mingming Zheng, Tianle Liu, Zhenyu Gao, et al..Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters,Journal of Petroleum Science and Engineering, 2019 ,178 (-):429-438 ( SCIE收录; EI收录; )[4]. Fang, Changliang; Zheng, Mingming; Lu, Hongzhi; Liu, Tianle; Jiang, Guosheng; Wu, Bisheng.A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore,JOURNAL OF NATURAL GAS SCIENCE AND ENGINEERING, 2018 ,52 ( ):348-355 ( SCIE收录; EI收录; )[5]. Wu, Jingjing; Zhang, Shaohe; Cao, Han; Zheng, Mingming; Sun, Pinghe; Luo, Xu.Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China,JOURNAL OF PETROLEUM SCIENCE AND ENGINEERING, 2018 ,164 ( ):675-684 ( SCIE收录; EI收录; )[6]. 郑明明, 韦猛, 曹函, 等..非开挖与明挖柔性管上土压力与变形对比分析,中南大学学报（自然科学版）, 2017 ,48 (12):3335-3343 ( EI收录; )[7]. 郑明明, 蒋国盛, 刘天乐, 等..钻井液侵入时水合物近井壁地层物性响应特征,地球科学, 2017 ,42 (3):453-461 ( EI收录; )[8]. Mingming Zheng, Guosheng Jiang, Tianle Liu, et al..Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures,Journal of Earth Science, 2016 ,27 (5):856-863 ( SCIE收录; )[9]. Tianle Liu, Guosheng Jiang, Ping Zhang, Jiaxin Sun, Huicui Sun, Ren Wang, Mingming Zheng*.A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments,Journal of Natural Gas Science and Engineering, 2016 ,33 (-):934-941 ( EI收录; SCIE收录; )[10]. 郑明明, 蒋国盛, 刘志超, 等..一种物性参数可控的人造长岩心制作技术与影响因素分析,地质科技情报, 2016 ,35 (6):222-229 ( 北大核心期刊; CSCD收录; )[11]. Mingming Zheng, Nilo Tsung, Eddie Oh, et al..A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology,Electronic Journal of Geotechnical Engineering, 2016 ,21 (11):4193-4201 ()[12]. Nilo Tsung, Mingming Zheng, Mohammad Najafi, et al..A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology,ASCE Pipelines Conference 2016, 2016 ,- (-):1420-1430 ( EI收录; 论文集; )[13]. 孙嘉鑫, 宁伏龙, 郑明明, 等..室内沉积物中天然气水合物形成数值模拟研究,天然气地球科学, 2015 ,26 (11):2172-2184 ( EI收录; )[14]. Mingming Zheng, Qian Sun, Guosheng Jiang, et al..Artificial cores technology of simulating In-Situ hydrate bearing sediment,Electronic Journal of Geotechnical Engineering, 2014 ,19 (z7):19029-19043 ( EI收录; )[15]. 郑明明, 蒋国盛, 宁伏龙, 等..模拟冻土区水合物地层骨架的人造岩心实验研究,天然气地球科学, 2014 ,25 (7):1120-1126 ( EI收录; )12[1]. Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir.. 2020. [2]. Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico.. 2020. [3]. Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters.. 2019. [4]. A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore.. 2018. [5]. Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China.. 2018. [6]. 非开挖与明挖柔性管上土压力与变形对比分析.. 2017. [7]. 钻井液侵入时水合物近井壁地层物性响应特征.. 2017. [8]. Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures.. 2016. [9]. A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments.. 2016. [10]. 一种物性参数可控的人造长岩心制作技术与影响因素分析.. 2016. [11]. A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology.. 2016. [12]. A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology.. 2016. [13]. 室内沉积物中天然气水合物形成数值模拟研究.. 2015. [14]. Artificial cores technology of simulating In-Situ hydrate bearing sediment.. 2014. [15]. 模拟冻土区水合物地层骨架的人造岩心实验研究.. 2014. [1]. Jingjing Wu, Shaohe Zhang, Han Cao, Mingming Zheng*, et al.. Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir.:, 2020 [2]. Mingming Zheng, Tianle Liu, Guosheng Jiang, et al.. Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico.:, 2020 [3]. Mingming Zheng, Tianle Liu, Zhenyu Gao, et al.. Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters.:, 2019 [4]. Fang, Changliang; Zheng, Mingming; Lu, Hongzhi; Liu, Tianle; Jiang, Guosheng; Wu, Bisheng. A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore.:, 2018 [5]. Wu, Jingjing; Zhang, Shaohe; Cao, Han; Zheng, Mingming; Sun, Pinghe; Luo, Xu. Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China.:, 2018 [6]. 郑明明, 韦猛, 曹函, 等.. 非开挖与明挖柔性管上土压力与变形对比分析.:, 2017 [7]. 郑明明, 蒋国盛, 刘天乐, 等.. 钻井液侵入时水合物近井壁地层物性响应特征.:, 2017 [8]. Mingming Zheng, Guosheng Jiang, Tianle Liu, et al.. Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures.:, 2016 [9]. Tianle Liu, Guosheng Jiang, Ping Zhang, Jiaxin Sun, Huicui Sun, Ren Wang, Mingming Zheng*. A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments.:, 2016 [10]. 郑明明, 蒋国盛, 刘志超, 等.. 一种物性参数可控的人造长岩心制作技术与影响因素分析.:, 2016 [11]. Mingming Zheng, Nilo Tsung, Eddie Oh, et al.. A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology.:, 2016 [12]. Nilo Tsung, Mingming Zheng, Mohammad Najafi, et al.. A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology.:, 2016 [13]. 孙嘉鑫, 宁伏龙, 郑明明, 等.. 室内沉积物中天然气水合物形成数值模拟研究.:, 2015 [14]. Mingming Zheng, Qian Sun, Guosheng Jiang, et al.. Artificial cores technology of simulating In-Situ hydrate bearing sediment.:, 2014 [15]. 郑明明, 蒋国盛, 宁伏龙, 等.. 模拟冻土区水合物地层骨架的人造岩心实验研究.:, 2014 [1]. . Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir. . , 2021.09.13 [2]. . Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico. . , 2021.09.13 [3]. . Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters. . , 2021.09.13 [4]. . A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore. . , 2021.09.13 [5]. . Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China. . , 2021.09.13 [6]. . 非开挖与明挖柔性管上土压力与变形对比分析. . , 2021.09.13 [7]. . 钻井液侵入时水合物近井壁地层物性响应特征. . , 2021.09.13 [8]. . Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures. . , 2021.09.13 [9]. . A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments. . , 2021.09.13 [10]. . 一种物性参数可控的人造长岩心制作技术与影响因素分析. . , 2021.09.13 [11]. . A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology. . , 2021.09.13 [12]. . A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology. . , 2021.09.13 [13]. . 室内沉积物中天然气水合物形成数值模拟研究. . , 2021.09.13 [14]. . Artificial cores technology of simulating In-Situ hydrate bearing sediment. . , 2021.09.13 [15]. . 模拟冻土区水合物地层骨架的人造岩心实验研究. . , 2021.09.13 1[1] .. Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir.,2021.09.13 [2] .. Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico.,2021.09.13 [3] .. Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters.,2021.09.13 [4] .. A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore.,2021.09.13 [5] .. Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China.,2021.09.13 [6] .. 非开挖与明挖柔性管上土压力与变形对比分析.,2021.09.13 [7] .. 钻井液侵入时水合物近井壁地层物性响应特征.,2021.09.13 [8] .. Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures.,2021.09.13 [9] .. A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments.,2021.09.13 [10] .. 一种物性参数可控的人造长岩心制作技术与影响因素分析.,2021.09.13 [11] .. A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology.,2021.09.13 [12] .. A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology.,2021.09.13 [13] .. 室内沉积物中天然气水合物形成数值模拟研究.,2021.09.13 [14] .. Artificial cores technology of simulating In-Situ hydrate bearing sediment.,2021.09.13 [15] .. 模拟冻土区水合物地层骨架的人造岩心实验研究.,2021.09.13 [1]. Experimental investigation of crack dynamic evolution induced by pulsating hydraulic fracturing in coalbed methane reservoir.:2021.09 - 2021.09 [2]. Large-scale and high-similarity experimental study of the effect of drilling fluid penetration on physical properties of gas hydrate-bearing sediments in the Gulf of Mexico.:2021.09 - 2021.09 [3]. Simulation of natural gas hydrate formation skeleton with the mathematical model for the calculation of macro-micro parameters.:2021.09 - 2021.09 [4]. A simplified method for predicting the penetration distance of cementing slurry in gas hydrate reservoirs around wellbore.:2021.09 - 2021.09 [5]. Fracability evaluation of shale gas reservoir-A case study in the Lower Cambrian Niutitang formation, northwestern Hunan, China.:2021.09 - 2021.09 [6]. 非开挖与明挖柔性管上土压力与变形对比分析.:2021.09 - 2021.09 [7]. 钻井液侵入时水合物近井壁地层物性响应特征.:2021.09 - 2021.09 [8]. Effect on the performance of drilling fluids at downhole rock surfaces at low temperatures.:2021.09 - 2021.09 [9]. A new low-cost drilling fluid for drilling in natural gas hydrate-bearing sediments.:2021.09 - 2021.09 [10]. 一种物性参数可控的人造长岩心制作技术与影响因素分析.:2021.09 - 2021.09 [11]. A preliminary study of the earth pressure exterted on pipelines installed by the open-cut method and trenchless technology.:2021.09 - 2021.09 [12]. A comparative study of soil pressure and deformation of pipes installed by the open-cut method and trenchless technology.:2021.09 - 2021.09 [13]. 室内沉积物中天然气水合物形成数值模拟研究.:2021.09 - 2021.09 [14]. Artificial cores technology of simulating In-Situ hydrate bearing sediment.:2021.09 - 2021.09 [15]. 模拟冻土区水合物地层骨架的人造岩心实验研究.:2021.09 - 2021.09 1出版专著Published Books1211科技奖励Science&Tech Awards1211发明专利Patents[1]. .TBM隧道掘进机管片扶正方法,, 2020 , : ()[2]. .一种高仿真固井胶结强度联合测试辅助装置,, 2020 , : ()[3]. .一种混凝土试压块模具,, 2020 , : ()[4]. .一种全自动维卡仪轮盘,, 2020 , : ()[5]. .可视化异形固井二界面胶结质量测试系统,, 2019 , : ()[6]. .一种快速便捷的固井水泥石渗透率测试装置,, 2019 , : ()12[1]. TBM隧道掘进机管片扶正方法.. 2020. 中国发明专利 [2]. 一种高仿真固井胶结强度联合测试辅助装置.. 2020. 实用新型专利 [3]. 一种混凝土试压块模具.. 2020. 实用新型专利 [4]. 一种全自动维卡仪轮盘.. 2020. 实用新型专利 [5]. 可视化异形固井二界面胶结质量测试系统.. 2019. 中国发明专利 [6]. 一种快速便捷的固井水泥石渗透率测试装置.. 2019. 实用新型专利 [1]. . TBM隧道掘进机管片扶正方法.:, 2020 [2]. . 一种高仿真固井胶结强度联合测试辅助装置.:, 2020 [3]. . 一种混凝土试压块模具.:, 2020 [4]. . 一种全自动维卡仪轮盘.:, 2020 [5]. . 可视化异形固井二界面胶结质量测试系统.:, 2019 [6]. . 一种快速便捷的固井水泥石渗透率测试装置.:, 2019 [1]. 韦猛, 郑明明, 宋宇, 等.. TBM隧道掘进机管片扶正方法. 中国发明专利. 201910207359.9, 2020.07.13 [2]. 王凯, 郑明明, 唐丞相, 等.. 一种高仿真固井胶结强度联合测试辅助装置. 实用新型专利. 201920561344.8, 2020.06.02 [3]. 赵馨远, 郑明明, 张翼, 等.. 一种混凝土试压块模具. 实用新型专利. 201921557856.3, 2020.06.30 [4]. 唐承相, 郑明明, 韦猛, 等.. 一种全自动维卡仪轮盘. 实用新型专利. 201921831090.3, 2020.06.30 [5]. 郑明明, 刘天乐, 蒋国盛, 等.. 可视化异形固井二界面胶结质量测试系统. 中国发明专利. 201811167812.X., 2019.12.27 [6]. 印雪林, 郑明明, 赵馨远, 等.. 一种快速便捷的固井水泥石渗透率测试装置. 实用新型专利. 201920369926.6, 2019.12.27 1[1] .. TBM隧道掘进机管片扶正方法.,2020.07.13 [2] .. 一种高仿真固井胶结强度联合测试辅助装置.,2020.06.02 [3] .. 一种混凝土试压块模具.,2020.06.30 [4] .. 一种全自动维卡仪轮盘.,2020.06.30 [5] .. 可视化异形固井二界面胶结质量测试系统.,2019.12.27 [6] .. 一种快速便捷的固井水泥石渗透率测试装置.,2019.12.27 [1]. TBM隧道掘进机管片扶正方法.:2021.09 - 2021.09 [2]. 一种高仿真固井胶结强度联合测试辅助装置.:2021.09 - 2021.09 [3]. 一种混凝土试压块模具.:2021.09 - 2021.09 [4]. 一种全自动维卡仪轮盘.:2021.09 - 2021.09 [5]. 可视化异形固井二界面胶结质量测试系统.:2021.09 - 2021.09 [6]. 一种快速便捷的固井水泥石渗透率测试装置.:2021.09 - 2021.09 1软件著作权Software Copyrights1211科研项目Research Projects[1]. .深水区低水化热早强微生物固井液体系研究,, 2019 , : ()[2]. .微生物基低水化热固井液体系研究,, 2018 , : ()[3]. .水合物分解对固井二界面胶结质量的影响机理,, 2017 , : ()12[1]. 深水区低水化热早强微生物固井液体系研究.. 2019. 教育部工程研究中心开放基金 [2]. 微生物基低水化热固井液体系研究.. 2018. 教育部重点实验室开放基金 [3]. 水合物分解对固井二界面胶结质量的影响机理.. 2017. 国家自然科学基金 [1]. . 深水区低水化热早强微生物固井液体系研究.:, 2019 [2]. . 微生物基低水化热固井液体系研究.:, 2018 [3]. . 水合物分解对固井二界面胶结质量的影响机理.:, 2017 [1]. . 深水区低水化热早强微生物固井液体系研究. 教育部工程研究中心开放基金. , 2021.09.13 [2]. . 微生物基低水化热固井液体系研究. 教育部重点实验室开放基金. , 2021.09.13 [3]. . 水合物分解对固井二界面胶结质量的影响机理. 国家自然科学基金. , 2021.09.13 1[1] .. 深水区低水化热早强微生物固井液体系研究.,2021.09.13 [2] .. 微生物基低水化热固井液体系研究.,2021.09.13 [3] .. 水合物分解对固井二界面胶结质量的影响机理.,2021.09.13 [1]. 深水区低水化热早强微生物固井液体系研究.纵向:2019.05 - 2021.04 [2]. 微生物基低水化热固井液体系研究.纵向:2018.10 - 2020.10 [3]. 水合物分解对固井二界面胶结质量的影响机理.青年基金:2018.01 - 2020.12 1相关资源均是用户自行上传分享，仅供学术交流之用?2019 环境与土木工程学院地质灾害防治与地质环境保护国家重点实验室技术支持：应子科技（成都）有限公司