李贺,1990.12-,山东济宁人,中共党员,教授,博导,湖南科技大学科技处副处长,江苏省优秀博士论文获得者,入选2023年全球前2%顶尖科学家,湖湘青年英才,湖南省优青获得者,湖南省青年科技人才(“荷尖”人才),中国职业安全健康协会瓦斯灾害防治与利用专业委员会青年委员,“全国高等学校矿业石油安全工程领域优秀青年科技人才”提名奖,湖南省应急管理专家,湘潭市C类高层次人才,湘潭市首届向上向善好青年,澳大利亚昆士兰大学访问学者,Int J Min Sci Technol、中国矿业大学学报、煤炭科学技术、煤田地质与勘探青年编委,矿山安全科学与工程国际会议(大会学术委员会委员),Journal of Safety and Sustainability首届青年编委,湖南科技大学高层次人才-湘江学者,湖南科技大学青年岗位能手。中国矿业大学本-博(2008-2018),主持国家自然科学基金面上项目、青年项目各1项、中国博士后科学基金面上项目、湖南省自然科学基金面上项目、青年项目各1项、湖南省教育厅科学基金2项、国家重点实验室基金2项、教育部重点实验室基金2项、湖南省学位与研究生教学改革研究项目(重点项目)1项;参与973计划课题1项、国家重点研发计划课题1项、澳大利亚采矿教育协会基金1项。发表学术论文70余篇(SCI收录49篇、EI收录4篇),单篇最高被引150次,4篇入选ESI高被引论文,2篇入选ESI热点论文,发表教研教改论文4篇。授权国家发明专利40项,实用新型专利12项。获第十三届湖南省高等教育教学成果一等奖1项(排名5)、中国专利优秀奖1项(排名3)、河南省科技进步一等奖1项(排名12)、煤炭工业科学技术一等奖2项(排名11、13)、中国职业安全健康协会科学技术二等奖1项(排名3)、中国安全科技进步二等奖2项(排名2、4)、中国安全科技进步三等奖1项(排名2)。
主要研究方向:
1)煤基甲烷资源化开发与防灾;
2)防火防爆与应急处置;
3)非常规油气安全高效开发;
Email:281323093@qq.com
科研项目:
[1] 国家自然科学基金面上项目(52274195),微波-酸化协同作用下煤体损伤改性与瓦斯增流机制研究,54万元,2023/01-2026/12,主持;
[2] 国家自然科学基金青年项目(51904103),微波辐射下煤体电磁热流固耦合效应及其改性增透机制,25万元,2020/01-2022/12,主持;
[3] 湖南省青年科技人才支持计划(“荷尖”人才),40万元,2022/03,主持;
[4] 湖南省自然科学基金优秀青年项目(2022JJ20024),微波-基质酸化协同作用下煤体损伤与瓦斯增流机制研究,20万元,2022/01-2024/12,主持;
[5] 中国博士后科学基金面上资助(2019M652765),脉冲微波辐射下煤体电磁热流固耦合及其增透机制,8万元,2019/06-2021/06,主持;
[6] 湖南省自然科学基金面上项目(2021JJ30254),基于纳米微泡材料的松软煤层瓦斯抽采钻孔抑喷与固结机制,5万元,2021/01-2023/12,主持;
[7] 湖南省自然科学基金青年项目(2019JJ50180),微波辐射下富水煤体电磁热耦合及其损伤机制研究,5万元,2019/01-2020/12,主持;
[8] 湖南省教育厅科学研究优秀青年项目(21B0465),离子环境下低透煤层微波强化增透机制研究,4万元,2021/10-2024/10,主持;
[9] 湖南省教育厅科学研究一般项目(18C0328),煤层气产出过程中水锁效应的微波热解除机制研究,1万元,2018/09-2020/12,主持;
[10] 煤炭资源与安全开采国家重点实验室开放基金(SKLCRSM20KF001),无机离子对煤体微波增透效果的影响机制研究,5万元,2020/01-2021/12,主持;
[11] 深部岩石力学与地下工程国家重点实验室开放基金(SKLGDUEK2008),微波辐射对页岩气储运特性的影响机制研究,5万元,2020/07-2022/06,主持;
[12] 湖南科技大学校级科研项目(E51882),高能微波辐射下富水煤体电磁热耦合及其损伤机制,5万元,2018/09-2020/09,主持;
[13] 江苏省研究生科研创新计划项目(KYCX17_1543),微波辐射下含水煤增透及瓦斯增产机制研究,2017/09-2018/09,主持;
[14] 国家重点基础研究发展计划(973计划)(2011CB201200),深部煤炭开发中煤与瓦斯共采理论,参与;
[15] 国家重点研发计划项目(2016YFC0801400),煤矿典型动力灾害风险判识及监控预警技术研究,参与;
[16] 国家自然科学基金面上项目(51974120),基于免疫机理的瓦斯异常涌出风险识别与防控理论研究,参与;
[17] 国家自然科学基金面上项目(51974121),高瓦斯低透气性煤层绳锯连续切割区域卸压增透机理研究,参与;
[18] 国家自然科学基金青年项目(51404261),巷道超前应力分布特征对突出危险性的响应机制,参与;
[19] 国家自然科学基金青年项目(51204169),瓦斯煤尘多相耦合体系的爆炸敏感性及其惰化机理研究,参与;
[20] Enhancing Coal Permeability Using Microwave Irradiation: A Non-Water Stimulation Approach(利用微波辐射提高煤体渗透率:一种非水力化方法),Mea Collaborative Research Grant Scheme(澳大利亚采矿教育协会),参与;
[21] 大倾角俯采长壁工作面采空区灌浆防灭火技术研究,中煤新集刘庄矿业有限公司,参与;
[22] 南家咀煤矿瓦斯(油层气)赋存及瓦斯涌出规律研究,陕西省子长县南家咀煤矿,参与;
[23] 突出煤层掘进工作面底板岩巷穿层水力冲孔增透及网络高效抽采技术研究,中国平煤神马集团,参与;
[24] 西部侏罗纪煤田瓦斯资源化开发及阶梯式利用关键技术研究与工程示范,陕西彬长矿业集团,参与;
[25] 永霏集团公共安全业务板块体系设计研究,湖南永霏特种防护用品有限公司,参与;
[26] 临涣煤矿13采区瓦斯赋存规律及治理技术研究,淮北矿业股份有限公司临涣煤矿,参与;
[27] 优化抽采钻孔直径提高预抽瓦斯效果研究,湖南省煤业集团嘉禾矿业有限公司,参与;
[28] 安源煤矿378工作面煤自燃防治技术研究,江西煤业集团有限责任公司安源煤矿,参与;
[29] 注册安全工程师培训课程体系设计研究,湖南永霏特种防护用品有限公司,参与;
[30] 岩浆岩侵蚀下煤层瓦斯赋存规律及治理技术研究,淮北矿业股份有限公司临涣煤矿,参与;
[31] 9134工作面下保护层保护效果扩界考察研究,淮北矿业股份有限公司临涣煤矿,参与;
[32] 孙疃煤矿远距离下保护层开采综合治理瓦斯技术及其应用研究,淮北矿业股份有限公司孙疃煤矿,参与。
Ø 学术论文:
[1] He Li, Shiliang Shi*, Baiquan Lin, Jiexin Lu, Qing Ye, Yi Lu, Zheng Wang, Yidu Hong, Xiangnan Zhu. Effects of microwave-assisted pyrolysis on the microstructure of bituminous coals. Energy (0016-2361), 2019.11.15, 187: 115986.(SCI, IF: 9, ESI 高被引论文,ESI 热点论文);被引150
[2] He Li, Chunshan Zheng*, Jiexin Lu, Li Tian, Yi Lu, Qing Ye, Wenke Luo, Xiangnan Zhu. Drying kinetics of coal under microwave irradiation based on a coupled electromagnetic, heat transfer and multiphase porous media model. Fuel (0016-2361), 2019.11.15, 256: 115966.(SCI, IF: 7.4, ESI 高被引论文,ESI 热点论文);被引76
[3] He Li, Shiliang Shi*, Baiquan Lin, Jiexin Lu, Yi Lu, Qing Ye, Zheng Wang, Yidu Hong, Xiangnan Zhu. A fully coupled electromagnetic, heat transfer and multiphase porous media model for microwave heating of coal. Fuel Processing Technology (0378-3820), 2019.6.15, 189: 49-61.(SCI, IF: 7.5, ESI 高被引论文);被引71
[4] He Li, Shiliang Shi*, Jiexin Lu, Qing Ye, Yi Lu, Xiangnan Zhu. Pore structure and multifractal analysis of coal subjected to microwave heating. Powder Technology (0378-3820). 2019.3.15, 346: 97-108.(SCI, IF: 5.2, ESI 高被引论文);被引125
[5] He Li, Xianhua Shen, Jiexin Lu, Yi Lu*, Shiliang Shi, Shuzhen Shao. Experimental and quantum chemical investigation on the inhibitory effects of Resveratrol on coal spontaneous combustion. Fuel (0016-2361), 2023.12.15, 354: 129297.(SCI, IF: 7.4);
[6] He Li, Qingyi Guo, Zheng Wang, Wei Yang*, Jiexin Lu, Yi Lu, Shiliang Shi. Molecular simulation of the adsorption and diffusion characteristics of CH4 in coal subjected to N-Methylpyrrolidone treatment. Fuel (0016-2361), 2023.11.15, 352: 129060.(SCI, IF: 7.4)
[7] He Li*, Jieyan Cao, Jiexin Lu, Yi Lu, Shiliang Shi, Zheng Wang, Xin Guo, Qing Ye. Exploring the Effect of Low-Temperature Oxidation on the Petrophysical Characteristics of Coal. ACS Omega (2470-1343), 2023, 8, 43: 40572–40586. (SCI, IF: 4.1);
[8] He Li*, Wuche Liu, Jiexin Lu, Yi Lu, Shiliang Shi, Zheng Wang, Qing Ye, Zhenzhen Jia. Effect of microwave-assisted acidification on the microstructure of coal: XRD, 1H-NMR, and SEM studies. International Journal of Mining Science and Technology (2095-2686), 2023.7, 33: 919-926. (SCI, IF: 11.8)被引1
[9] He Li, Xiaolong Wang, Jiexin Lu*, Yi Lu, Shiliang Shi, Zheng Wang, Ting Liu, Qing Ye, Zhenzhen Jia. Study on the dynamics mechanism of methane diffusion in coal under microwave heating. Fuel (0016-2361), 2023.1.1, 331: 125758.(SCI, IF: 7.4);被引12
[10] He Li*, Jiawei He, Jiexin Lu, Baiquan Lin, Yi Lu*, Shiliang Shi, Qing Ye. A review of laboratory study on enhancing coal seam permeability via chemical stimulation. Fuel (0016-2361), 2022.12.15, 330: 125561.(SCI, IF: 7.4);被引18
[11] He Li, Chaoping Xu, Guanhua Ni*, Jiexin Lu, Yi Lu, Shiliang Shi, Min Li, Qing Ye. Spectroscopic (FTIR, 1H-NMR) and SEM investigation of physicochemical structure changes of coal subjected to microwave-assisted oxidant stimulation. Fuel (0016-2361), 2022.6.1, 317: 123473. (SCI, IF: 7.4);
[12] He Li, Li Tian, Bingxiang Huang, Jiexin Lu, Shiliang Shi, Yi Lu, Fei Huang, Yong Liu, Xiangnan Zhu. Experimental Study on Coal Damage Subjected to Microwave Heating. Rock Mechanics and Rock Engineering (0723-2632), 2020.8.29, 53: 5631-5640.(SCI, IF: 6.2);被引11
[13] He Li, Baiquan Lin*, Yidu Hong, Tong Liu, Huang Zhanbo, Rui Wang, Zheng Wang. Assessing the moisture migration during microwave drying of coal using low field nuclear magnetic resonance. Drying Technology (0737-3937), 2017.10.3, 36(5): 567-577.(SCI, IF: 3.3);被引28
[14] He Li, Baiquan Lin*, Zhongwei Chen, Yidu Hong, Chunshan Zheng. Evolution of coal petrophysical properties under microwave irradiation stimulation for different water saturation conditions. Energy Fuel (0887-0624), 2017.8.2, 31(9): 8852-8864.(SCI, IF: 4.654);被引24
[15] He Li, Baiquan Lin*, Hong Yidu, Gao Yabin, Yang Wei, Liu Tong, Wang Rui, Huang Zhanbo. Effects of in-situ stress on the stability of a roadway excavated through a coal seam. International Journal of Mining Science and Technology (2095-2686), 2017.11, 27(6): 917-927.(SCI, IF: 11.8);被引18
[16] He Li, Baiquan Lin, Wei Yang*, Chunshan Zheng, Yidu Hong, Yabin Gao, Tong Liu, Shiliang Wu. Experimental study on the petrophysical variation of different rank coals with microwave treatment. International Journal of Coal Geology (0166-5162), 2016.2.15, 154-155: 82-91.(SCI, IF: 5.6);被引124
[17] He Li, Baiquan Lin*, Wei Yang, Yabin Gao, Tong Liu. Effects of an underlying drainage gallery on coal bed methane capture effectiveness and the mechanical behavior of a gate road. Journal of Natural Gas Science and Engineering (1875-5100), 2015.11, 27: 616-631.(SCI, IF: 3.859);被引25
[18] Jiawei He, He Li, Jiexin Lu, Wei Yang*, Baiquan Lin, Meng Liu*, Yi Lu, Shiliang Shi, Zheng Wang, Qing Ye. Variations in the pore structure and fluid mobility under anionic surfactant assisted matrix acidification of coal based on nuclear magnetic resonance T1-T2 spectra. Fuel (0016-2361), 2024.2.1, 355: 129488. (SCI, IF: 7.4);
[19] Jiawei He, He Li, Wei Yang*, Jiexin Lu, Yi Lu, Ting Liu, Shiliang Shi. Experimental study on erosion mechanism and pore structure evolution of bituminous and anthracite coal under matrix acidification and its significance to coalbed methane recovery. Energy (0360-5442), 2023.11.15, 283:128485. (SCI, IF: 9);
[20] Chaoping Xu, He Li*, Jiexin Lu, Shiliang Shi, Qing Ye, Min Li, Zheng Wang. An investigation into the modification of microwave-assisted oxidation in the macromolecular structure of coal via XRD and Raman spectroscopy. Fuel (0016-2361), 2023.4.15, 338: 127192. (SCI, IF: 7.4) ;被引9
[21] Chaoping Xu, He Li*, Yi Lu*, Ting Liu, Jiexin Lu, Shiliang Shi, Qing Ye, Zhenzhen Jia, Zheng Wang. Influence of microwave-assisted oxidant stimulation on pore structure and fractal characteristics of bituminous coal based on low-temperature nitrogen adsorption. Fuel (0016-2361), 2022.11.1, 327: 125173.(SCI, IF: 7.4);被引13
[22] Zheng Wang*, Baiquan Lin*, Wei Yang, He Li, Minghua Lin. Fracture and pore development law of coal under organic solvent erosion. Fuel (0016-2361), 2022.1.1, 307: 121815.(SCI, IF: 7.4);被引9
[23] Yi Lu, He Li*, Deming Wang,Xingyu Shi, He Li, Yunfei Zhu, Qing Ye, Jiexin Lu. Discharge and ignition characteristics from indentation fracture of coal mine roof. Fuel (0016-2361), 2021.5.1, 291: 120208.(SCI, IF: 7.4);被引10
[24] Li Min, Yi Lu*, Shiliang Shi, He Li, Zhaojun Tian, Qing Ye, Jiexin Lu. Piezoelectric effect and ignition properties of coal mine roof sandstone deformation and fracture. Fuel (0016-2361), 2021.4.15, 290: 120007.(SCI, IF: 7.4);被引25
[25] Jiexin Lu, He Li, Shiliang Shi, Bingxiang Huang, Yi Lu, Min Li, Qing Ye. Microwave-Induced Microstructure Evolution of Coal and Its Effects on the Methane Adsorption Characteristic. Energy&Fuels (0887-0624). 2021.2.18;35:4081-4090.(SCI, IF: 4.654);
[26] Bo You*, Jiaxin Xu, Shiliang Shi, Heqing Liu, Yi Lu, He Li. Effect of Stress and Water Pressure on Permeability of Fractured Sandstone Based on Response Surface Method. Frontiers in Earth Science (2296-6463), 2020, 8.(SCI, IF: 2.9);被引4
[27] Zhuohua Yang, Qing Ye*, Zhenzhen Jia, He Li. Numerical Simulation of Pipeline-Pavement Damage Caused by Explosion of Leakage Gas in Buried PE Pipelines. Advances in Civil Engineering (1687-8086), 2020.9.15, 26: 193-204.(SCI, IF: 1.8);被引11
[28] Yi Lu, He Li*, Jiexin Lu, Shiliang Shi, Geoff G.X. Wang, Qing Ye, Runqiu Li, Xiangnan Zhu. Clean up water blocking damage in coalbed methane reservoirs by microwave heating: Laboratory studies. Process Safety and Environmental Protection (0957-5820), 2020.6, 138: 292-299.(SCI, IF: 7..8);被引32
[29] Chunshan Zheng*, He Li*, Mehmet Kizil*, Bingyou Jiang*, Sheng Xue*, Wei Yang*, Zhongwei Chen*. Performance enhancement of horizontal underground-to-inseam gas drainage boreholes with double-phase-grouting sealing method for coal mining safety and clean gas resource. Journal of Natural Gas Science and Engineering (1875-5100), 2020.4, 76: 103179.(SCI, IF: 3.859);被引19
[30] Yi Lu, Wangxin Gu, Geoff G. X. Wang, He Li, Shiliang Shi, Hui-yong Niu, Qing Ye. Numerical Assessment of the Influences of the Coal Spontaneous Combustion on Gas Drainage Methods Optimization and Its Application. Combust Science&Technology (0010-2202), 2020,193(12): 2158-2175.(SCI, IF: 1.9);被引6
[31] Yi Lu*, Yilun Liu, Shiliang Shi, Geoff G.X. Wang, He Li, Tao Wang. Micro-particles stabilized aqueous foam for coal spontaneous combustion control and its flow characteristics. Process Safety and Environmental Protection (0957-5820), 2020.7, 139: 262-272.(SCI, IF: 7.8);被引41
[32] Yi Lu*, Zhihong Yan, Shiliang Shi, Geoff Wang, He Li, Huiyong Niu, Zhiguo Guo, Ping Wang. Delineation and Prevention of the Spontaneous Combustion Dangerous Area of Coal in a Regenerated Roof: A Case Study in the Zhoujing Coal Mine, China. Energy&Fuels (0887-0624), 2020, 34(5): 6401-6413.(SCI, IF: 4.654);被引12
[33] Chunshan Zheng, Bingyou Jiang*, Sheng Xue, Zhongwei Chen, He Li. Coalbed methane emissions and drainage methods in underground mining for mining safety and environmental benefits: A review. Process Safety and Environmental Protection (0957-5820), 2019.7, 127: 103-124.(SCI, IF: 7.8);被引120
[34] Zheng Wang, Baiquan Lin*, He Li, Yidu Hong, Wei Yang ,Xiangnan Zhu, Yanchi Liu. Acetone erosion and its effect mechanism on pores and fractures in coal. Fuel (0016-2361), 2019.10.1, 253: 1282-1291.(SCI, IF: 7.4);被引11
[35] Zhenzhen Jia, Qinng Ye*, Haizhen Wang, He Li, Shiliang Shi. Numerical Simulation of a New Porous Medium Burner with Two Sections and Double Decks. Processes (2227-9717), 2018, 6(10): 185.(SCI, IF: 3.5);被引10
[36] Yidu Hong, Bai-quan Lin, Wen Nie*, Chuan-jie Zhu, Zheng Wang, He Li. Microwave irradiation on pore morphology of coal powder. Fuel (0016-2361), 2018.9.1, 227: 434-447.(SCI, IF: 7.4);被引31
[37] Baiquan Lin, He Li*, Zhongwei Chen, Chunshan Zheng, Yidu Hong, Zheng Wang. Sensitivity analysis on the microwave heating of coal: A coupled electromagnetic and heat transfer model. Applied Thermal Engineering(1359-4311), 2017.11.5, 126: 949-962.(SCI, IF: 6.4);被引138
[38] Chunshan Zheng, Baiquan Lin, Mehmet S.Kizil, Saiied M.Aminossadati, He Li, Zhongwei Chen*. Analysis on the multi-phase flow characterization in cross-measure borehole during coal hydraulic slotting. International Journal of Mining Science and Technology (2095-2686), 2018.7, 28(4): 701-705.(SCI, IF: 11.8);被引20
[39] Yidu Hong*, Bai-quan Lin, He Li, Hua-ming Dai, Chuan-jie Zhu, Hao Yao. Three-dimensional simulation of microwave heating coal sample with varying parameters. Applied Thermal Engineering (1359-4311), 2016.1.25, 93: 1145-1154.(SCI, IF: 6.4);被引140
[40] Yidu Hong, Bai-quan Lin, Chuan-jie Zhu, He Li. Effect of microwave irradiation on petrophysical characterization of coals. Applied Thermal Engineering (1359-4311), 2016.6.5, 102: 1109-1125.(SCI, IF: 6.4);被引72
[41] Yidu Hong, Bai-quan Lin*, Chuan-jie Zhu, He Li. Influence of Microwave Energy on Fractal Dimension of Coal Cores: Implications from Nuclear Magnetic Resonance. Energy&Fuels (0887-0624), 2016, 30(12): 10253-10259.(SCI, IF: 4.654);被引27
[42] Baiquan Lin*, He Li, Desheng Yuan, Ziwen Li. Development and application of an efficient gas extraction model for low-rank high-gas coal beds. International Journal of Coal Science& Technology (2095-8293), 2015.5.15, 2: 76-83;被引23
[43] Yabin Gao*, Baiquan Lin, Wei Yang*, Ziwen Li, Yuan Pang, He Li. Drilling large diameter cross-measure boreholes to improve gas drainage in highly gassy soft coal seams. Journal of Natural Gas Science and Engineering (1875-5100), 2015.9, 26: 193-204.(SCI, IF: 3.859);被引70
[44] Xi Wu, Chunshan Zheng*, He Li*, iexin Lu, Yi Lu, Shiliang Shi, Yuannan Zheng, Zheng Wang. Elucidation of evolutionary characteristics of pore structure in anthracite through microwave-LN2 freeze–thaw cycling. Fuel (0016-2361), 2023.11.15, 352:128989. (SCI, IF: 7.4); 被引2
[45] Jiexin Lu, Chunshan Zheng*, Wuche Liu, He Li, Shiliang Shi*, Yi Lu, Qing Ye, Yuannan Zheng. Evolution of the pore structure and fractal characteristics of coal under microwave-assisted acidification, Fuel (0016-2361), 2023.9.1,347:128500.(SCI, IF: 7.4); 被引5
[46] Jiexin Lu, Xiaolong Wang, He Li*, Shiliang Shi*, Wei Yang, Yi Lu, Shuzhen Shao, Qing Ye. Molecular insights into the methane adsorption capacity of coal under microwave irradiation based on solid-state 13C-NMR and XPS, Fuel (0016-2361), 2023.5.1, 339: 127484.(SCI, IF: 7.4); 被引10
[47] Jiexin Lu, Shiliang Shi*, He Li*, Yi Lu, Xingyu Shi, Qing Ye, Min Li.Thermodynamic analysis of moist coal during microwave heating using coupled electromagnetic, multi-phase heat and mass transfer model. Chemical Engineering Science (0009-2509),2022.6.29, 255: 117690.(SCI, IF: 4.7);被引9
[48] Baiquan Lin*, Zheng Wang*, Wei Yang, He Li, Yidu Hong. Fracture Development Characteristics of Coal under Organic Solvent Erosion and Its Nondestructive Testing Method. Energy&Fuels (0887-0624), 2021, 35(17): 13788−13800.(SCI, IF: 4.654);被引5
[49] Zhaojun Tian, Yi Lu, Shimin Liu, Shiliang Shi, He Li, Qing Ye. Application of Inorganic Solidified Foam to Control the Coexistence of Unusual Methane Emission and Spontaneous Combustion of Coal in the Luwa Coal Mine, China. Combustion Science and Technology (0010-2202), 2020, 192(4): 638-656.(SCI, IF:2.133);被引13
[50] 李贺,沈先华,田丽,路洁心,鲁义,曾钢.基于FDS的细水雾抑制熄灭带式输送机火灾研究.煤矿安全,2023,54(09):53-59
[51] 李贺,田丽,曾钢,鲁义,路洁心,施式亮.基于FDS的风速对矿井火灾蔓延规律的影响研究.中国安全生产科学技术(1673-193X),2022,18(05): 143-149.
[52] 李贺,林柏泉,洪溢都,杨威,刘统,黄展博,王瑞.微波辐射下煤体孔裂隙结构演化特性. 中国矿业大学学报(1000-1964), 2017, 46(6): 1194-1201.(EI);(Li, He et al. 2022)
[53] 李贺,林柏泉,黄展博,滕飞,杨威,高亚斌,刘统,王瑞.不同原岩应力方向下石门揭煤时应力与位移演化特征. 煤炭科学技术(0253-2336), 2017, 45(10): 88-95;4
[54] 李贺. 高巷道风表移动路线的改良. 山西焦煤科技(1672-0652), 2011, 4;
[55] 沈先华,李贺*, 鲁义,路洁心,施式亮.祁南煤矿火成岩侵蚀对煤层瓦斯赋存及突出灾害的影响.矿业工程研究(1674-5876),2023,38(01):29-35.
[56] 徐超平,李贺*,鲁义,路洁心,施式亮.软煤瓦斯抽采钻孔失稳特性及控制技术研究现状.矿业安全与环保(1008-4495),2022,49(03): 131-135.
[57] 王小龙,李贺*,鲁义,路洁心,施式亮.基于分子模拟的煤中甲烷吸附扩散行为研究现状及展望. 能源与环保(1003-0506),2022,44(01):189-195;
[58] 刘五车,李贺*,鲁义,路洁心,施式亮,李敏.低透煤层化学改性增透技术研究现状及展望. 能源与环保(1003-0506),2022,44(01):207-214;
[59] 田丽,李贺*,徐超平,刘五车,王小龙.临涣煤矿瓦斯防治技术研究.能源与环保(1003-0506), 2021,43(02): 19-23;
[60] 丁海洋, 罗文柯,万芳芳,施式亮,汤铸,鲁义,李贺.上保护层开采双工作面卸压数值模拟. 矿业工程研究(1674-5876), 2021,36(02): 54-64;
[61] 郭春晖,李贺,袁晗,李文豪,朱松松.保护层开采瓦斯治理与保护范围考察. 湖南科技大学学报(自然科学版)(1672-7835), 2020, 35(03): 7-12;
[62] 宣啸,罗文柯,李贺,黄妍,陆俊翔,王成龙.基于灰色理论对临涣煤矿六采区煤层瓦斯压力的预测优化.矿业工程研究(1674-5876), 2020,35(04): 52-60;
[63] 曾明圣,施式亮,鲁义,李贺,吴宽.煤与瓦斯共生灾害现状研究. 能源与环保(1003-0506), 2020,42(08): 6-9;
[64] 凌紫城,施式亮,鲁义,李贺,吴宽.铁箕山煤矿2号煤层自然发火标志气体及临界值确定. 能源与环保(1003-0506), 2020,42(08): 33-36+41;
[65] 高亚斌,林柏泉,杨威,李贺,李子文. 高突煤层穿层钻孔“钻-冲-割”耦合卸压技术及应用. 采矿与安全工程学报(1673-3363), 2017, 34(1): 177- 184.(EI);29
[66] 高亚斌,杨威,李贺,郝志勇.石钻粉制备注浆材料特性研究. 煤炭学报(0253-9993), 2015, 40 (04): 816-822.(EI);19
[67] 焦汉林,杨胜强,李贺.煤层倾角变化对石门揭煤突出危险性影响的数值模拟研究. 煤炭技术(1008-8725), 2015, 34(04): 150-153;5
[68] 高亚斌,杨威,郝志勇,李子文,李贺.不渗透小断层群瓦斯异常赋存特点及防治研究. 中国矿业大学学报(1000-1964), 2013, 42(06): 989-995.(EI);24
[69] 路洁心,李贺.穿层定向水力压裂技术的应用. 山西焦煤科技(1672-0652), 2011,35(05):39-41+50; 5
[70] 秦培建,张清勇,李贺,吴郗,徐超平.临涣井田岩浆侵入活动对煤体的影响规律..安全(1002-3631),2023,44(01):60-64;
[71] 施式亮,曾明圣,李贺,鲁义.煤自燃与瓦斯共生灾害演化与预警.煤矿安全(1003-496X),2022,53(09):9-16;
[72] 朱绍飞,叶青,李贺,贾真真,沈子鹤,杨卓华.巷道空间内瓦斯爆炸冲击波传播的数值模拟. 矿业工程研究(1674-5876), 2019, 34(03): 23-30;
[73] 吴晓亮,路洁心,李贺. 水压爆破技术的应用. 山西焦煤科技(1672-0652), 2011, 35(06):38-39+53; 6。
Ø 教研教改论文:
[1] 李贺,徐超平,施式亮,鲁义.面向“新业态”的安全工程专业人才培养体系研究. 科技视界(2095-2457),2021,19(09):18-19;
[2] 李贺,王小龙, 施式亮,田丽.安全工程专业“机械安全技术”课程教学改革探索. 科技视界(2095-2457),2021.13(12):30-31;
[3] 李贺,田丽,施式亮,鲁义.安全工程专业“职业健康安全管理体系”课程教学改革. 科技视界(2095-2457),2020.15(01):48-49;
[4] 李贺,田丽, 施式亮,鲁义.安全工程专业“环境工程概论”课程教学探索与实践. 科技视界(2095-2457),2019。
Ø 授权发明专利:
[1] 底板割缝与酸侵相协同的软煤瓦斯抽采钻孔抑喷方法,ZL202110010884.9,CN112727403B,2022.6.14,排名1(李贺、徐超平、路洁心、鲁义、郑春山、李敏、施式亮);
[2] 泡沫铜充填与超声波破岩相协同抑制瓦斯抽采喷孔的方法,ZL202011325161.X,CN112228146B,2022.3.22,排名1(李贺、徐超平、鲁义、路洁心、郑春山、施式亮、李敏);
[3] 基于微波辐射的极薄煤层群原位气化开采方法,ZL201910230519.1,CN110067549B,2021.8.20,排名1(李贺、施式亮、路洁心、叶青、鲁义、朱邵飞);
[4] 一种可视化封孔材料裂隙封堵性能测试装置及方法, ZL202110006540.0,CN112727444 B,2023.7.25, 排名1(李贺、路洁心、王小龙、鲁义、施式亮、李敏、叶青)
[5] 一种用于高硫煤层瓦斯抽采的硫化氢净化装置及方法,ZL202011338787.4,CN112604420B,2023.8.11,排名1(李贺、路洁心、鲁义、施式亮、李敏、叶青、郑春山、王正、徐超平)
[6] 一种水力割缝与酸化脱矿相协同的煤层增透方法,ZL201910587977.0,CN110130866A, 2021.7.30,排名2(路洁心、李贺、田丽、鲁义、施式亮、叶青);
[7] 一种酸碱协同抽采高硫煤层瓦斯与治理硫化氢的方法,ZL 202111055560.3,CN 113550784B,2022.5.24,排名2(路洁心、李贺、施式亮、鲁义、徐超平、李敏、叶青);
[8] 一种微波液氮协同冻融煤层增透方法,ZL201610941194.4,CN106285605B,2019.6.4,排名2(林柏泉、李贺、洪溢都、杨威、刘统、王瑞、黄展博);
[9] 一种微波与超声波相协同的煤层气强化开采方法,ZL201610941192.5,CN106499366B,2019.4.26,排名2(林柏泉、李贺、王一涵、路洁心、王正、洪溢都) ;
[10] 一种微波辅助超临界二氧化碳循环压裂系统及方法,ZL201610941193.X,CN106285604B,2019.3.1,排名2(林柏泉、李贺、杨威、洪溢都、刘统);
[11] 一种微波辐射孔内汽化水力冲孔方法,ZL201511019352.2,CN105507812B,2017.8.11,排名2(林柏泉、李贺、洪溢都、黄展博、王瑞);
[12] 一种基于微波辐照的煤层水力压裂强化增透方法,ZL201511018015.1,CN105525901B,2017.10.24,排名2;(林柏泉、李贺、洪溢都、刘统、杨威、黄展博、王瑞)
[13] 一种微波辅助抽提与水力压裂相协同的煤层增透方法,ZL201511019052.4,CN105484720B,2017.10.24,排名2(林柏泉、李贺、洪溢都、刘统、王瑞、杨威、黄展博);
[14] 一种组合式石门揭煤方法,ZL201310465569.0,CN103510957B,2016.4.20,排名2(林柏泉、李贺、杨威、高亚斌、王迪);
[15] 一种缓倾斜特厚煤层石门揭煤方法,ZL201310464564.6,CN103510958B,2016.8.10,排名2(林林柏泉、李贺、杨威、王迪、高亚斌);
[16] 本煤层瓦斯抽采钻孔双管抽采方法,ZL201210542199.1,CN103075179B,2014.12.10,排名2(林柏泉、李贺、高亚斌、杨威);
[17] 浅埋煤层堵漏风与氧化产热吸排的浆泡材料及其制备方法,ZL 202011343325.1,CN 112480648B,2022.5.3,排名3;(鲁义、陈健、李贺、李敏、吴芳华、田兆君);
[18] 钻孔丙酮侵袭与水力压裂相结合的交替式煤层增透方法,ZL201710127893.X,CN106930746B,2019.6.4,排名3(林柏泉、王正、李贺、杨威、洪溢都);
[19] 一种微波热风耦合注热的煤体增透方法,ZL201710127895.9,CN106869991B,2019.2.19,排名3(林柏泉、王正、李贺、杨威、洪溢都);
[20] 一种瓦斯抽采钻孔的封孔方法,ZL201210589282.4,CN103075128B,2015.7.29,排名3(林柏泉、高亚斌、李贺、路洁心、李子文);
[21] 一种高瓦斯煤层冲割压抽一体化的卸压增透瓦斯抽采方法,ZL201410334414.4,CN104131832B,2016.8.17,排名3(林柏泉、杨威、李贺);
[22] 一种递进掩护式瓦斯卸压抽采方法,ZL201710165698.6,CN106894837B,2018.9.25,排名4(林柏泉、刘统、王一涵、李贺、杨威、刘厅、高亚斌、胡欣然);
[23] 一种底板岩巷穿层卸压钻孔充填加固方法,ZL201310189127.8,CN103291354B,2015.6.10,排名4(林柏泉、高亚斌、杨威、李贺、沈春明);
[24] 一种煤岩同采保护层与被保护层协同开采方法,ZL201510939170.0,CN105507903A,2018.1.2,排名4(林柏泉、刘统、杨威、李贺、高亚斌、王瑞、黄展博);
[25] 一种确定关键块裂隙最佳胶结时间的再生顶板控制方法,ZL 202010777977.X,CN 111911195B,2022.3.4,排名4(鲁义、陈健、余伟健、李贺、吴芳华、谷旺鑫);
[26] 一种用于再生顶板的自愈型封堵材料及其制备方法,ZL 202010899101.2,CN 111944277B,2022.5.3,排名4(鲁义、晏志宏、李敏、李贺、牛会永、田兆君、路洁心);
[27] 有限差分法与相似实验预测再生顶板漏风裂隙发育的方法,ZL 202010777410.2,CN 111914456B,2022.5.3,排名5(鲁义、陈健、晏志宏、王平、李贺、谷旺鑫);
[28] 一种防止极松软煤层钻孔施工过程中钻孔喷孔的施工方法,ZL 202110245895.5,CN 112832848B,2022.5.20,排名5(鲁义、谷旺鑫、施式亮、李树清、李贺、李敏、晏志宏);
[29] 一种用于粉煤原位固结改性的纳米微泡材料及其制备方法,ZL201910819453.X,CN110564391B,2021.6.29,排名5(鲁义、谷旺鑫、吴宽、施式亮、李贺、叶青);
[30] 一种确定松软煤层抽采钻孔最佳塑性区范围的方法,ZL202010120222.2,CN111101999B,2021.2.2,排名5(鲁义、谷旺鑫、晏志宏、施式亮、李贺、吴宽);
[31] 一种基于采空区漏风场优化的煤与瓦斯共生灾害防治方法,ZL202010354601.8,CN111425245B,2021.6.29,排名5(施式亮、曾明圣、鲁义、吴宽、李贺、凌紫城);
[32] 一种煤岩同采工作面的煤岩分选与利用方法,ZL201610474111.5,CN106401586B,2019.2.22,排名5(林柏泉、刘统、杨威、刘厅、李贺、黄展博、王瑞);
[33] 一种高瓦斯突出煤层“钻‑冲‑割”耦合卸压增透方法,ZL201510866018.4,CN105422069B,2017.8.25,排名5(林柏泉、刘统、高亚斌、杨威、李贺、黄展博、王瑞);
[34] 一种高突煤层穿层钻孔网络化加固方法,ZL201310188024.X,CN103306713B,2015.12.9,排名5(林柏泉、高亚斌、杨威、沈春明、李贺);
[35] 一种煤层采场优势瓦斯运移通道阶梯式构建方法,ZL201710165699.0,CN106837408A,2018.8.21,排名5(林柏泉、刘统、刘厅、杨威、李贺、黄展博、王瑞、王一涵);
[36] 一种网络化优势瓦斯运移通道构建及瓦斯导流抽采方法,ZL201710166050.0,CN106948859A,2018.7.27,排名5(林柏泉、刘统、刘厅、杨威、李贺、王瑞、王正);一种用于消防员防护服的隔热内衬及其制作方法,ZL201910176138.X,CN109805478B,2020.6.19,排名6(鲁义、杨帆、邵淑珍、陈世强、刘勇、李贺、汪鹏);
[37] 一种高瓦斯极松软煤层瓦斯抽采钻孔的施工方法,ZL201910719550.1,CN110344758B,2020.8.25,排名第6(鲁义、谷旺鑫、施式亮、尹红球、吴宽、李贺、游波);
Ø 授权实用新型专利:
[1] 用于高硫煤层瓦斯抽采的硫化氢净化装置ZL202111055560.3,ZL202022765268.8,CN214019827U,2021.8.24,排名2;
[2] 用于松软煤层钻孔防喷的微泡材料制备一体化装置,ZL202022746506.0,CN214026801U,2021.8.24,排名2;
[3] 可视化封孔材料裂隙封堵性能测试装置,ZL202120010844.X,CN214035640U,2021.8.24,排名2;
[4] 可拆卸式自救缓降器绳索的固定装置,ZL202022902859.5,CN214018960U,2021.8.24,排名3;
[5] 检测煤自燃产热产气特性对瓦斯浓度场影响的装置,ZL202021254279.3,CN212301385U,2021.1.5,排名5;
[6] 用于极松软煤层抽采钻孔的瓦斯收集装置,ZL201921227334.7,CN210396798U,2020.4.24,排名6;
[7] 用于防灭火的膏体泡沫产生装置,ZL201920075199.2,CN209422810U,2019.9.24,排名6。
Ø 获奖及荣誉:
[1] 微波辐射下煤体热力响应及其流-固耦合机制研究,江苏省优秀博士学位论文,2019;
[2] Spectroscopic (FTIR, 1H NMR) and SEM investigation of physicochemical structure changes of coal subjected to microwave-assisted oxidant stimulation 基于红外光谱、核磁共振 和扫描电镜的微波-氧化作用下煤体理化结构演化机制研究,湘潭市自然科学优秀学术论文,2023,排名1(李贺、徐超平、倪冠华);
[3] 一种高瓦斯煤层冲割压抽一体化卸压增透瓦斯抽采方法,中国专利优秀奖,2018,排名3(林柏泉、杨威、李贺);
[4] 一流引领,两需驱动,三元协同,安全工程人才培养体系创新的探索与实践,第十三届湖南省高等教育教学成果一等奖,2022,排名5(施式亮、鲁义、李润求、游波、李贺、刘勇、李敏、李石林、张术琳);
[5] 再生顶板裂隙漏风诱发煤自燃基础理论及浆泡材料抑燃技术,第三届安全科技进步二等奖,2021,排名2(鲁义、李贺、施星宇、李敏、吴芳华、邵国华、谷旺鑫、于顺才、丁仰卫、邵淑珍);
[6] 含瓦斯煤岩裂隙漏风氧化致灾机制及浆泡材料防控技术,中国职业安全健康协会科学技术二等奖,2020,排名3(鲁义、施式亮、李贺、李敏、张孝强、亓冠圣、晏志宏、路洁心、谷旺鑫);
[7] 基于人体生理响应机制的特种作业防护服研发,第三届安全科技进步二等奖,2021,排名4(鲁义、李敏、游波、李贺、邵淑珍、刘艺伦、路洁心、谷旺鑫、张艺馨、李文辉);
[8] 基于信息耦合的煤矿瓦斯与煤自燃共生灾害协同防控技术,中国安全科技进步三等奖,2019,排名2(鲁义、李贺、游波、田兆君、张巨峰);
[9] 高瓦斯突出煤层“钻-冲-割”耦合卸压及瓦斯高效抽采技术,河南省科学技术进步一等奖,2016-J-15-R12/15,2016,排名12(康国峰、林柏泉、张建国、魏思祥、杨威、王满、刘庆军、吴建亭、王玉杰、高亚斌、吴昕、李贺、刘厅、刘统、杨继东);
[10] 瓦斯资源化开发及阶梯式利用关键技术研究与工程示范,煤炭工业科学技术一等奖,2015-127-R13,2015,排名13(林柏泉、李厚志、李孝波、原德胜、李庆钊、李继昌、杨威、陈跟马、李子文、郭魏虎、代华明、张进军、李贺、刘宁川、王福军);
[11] 高瓦斯突出煤层“钻-冲-割”耦合卸压及瓦斯高效抽采技术,河南省工业和信息化科技成果一等奖,HNGXJ- 20151146-12,2015;
[12] 高瓦斯突出煤层强弱耦合结构石门揭煤关键技术,煤炭工业科学技术一等奖,2014-120-R11,2014,排名11(林柏泉、翟成、杨威、郝志勇、朱传杰、吴海进、李庆钊、李全贵、倪冠华、张连军、李贺、李子文、邹全乐、高亚斌、梁爱莉);
[13] 一流引领,两需驱动,三元协同,安全工程人才培养体系创新的探索与实践,湖南科技大学教学成果一等奖,2022;排名5(施式亮、鲁义、李润求、游波、李贺、刘勇、李敏、李石林、张术琳);
[14] 瓦斯抽采钻孔注浆密封固液界面耦合作用机理研究,江苏省普通高等学校本专科优秀毕业设计(论文)二等奖,2012。
上一篇:鲁义
