基本信息:
姓名:蔚立元
出生年月:1982.08
学位/职称:博士、教授、博士生导师
人才称号:国家重大人才工程项目(青年)入选者
研究领域:岩石动力学、裂隙岩体渗流
地下工程稳定控制理论与防灾减灾技术
招生专业:岩土工程、防灾减灾工程及防护工程、
桥梁与隧道工程、土木水利工程
电子邮箱: yuliyuan@cumt.edu.cn
个人简介
蔚立元,男,汉族,山东东平人,教授、博士生导师,国家重大人才工程项目(青年)入选者。现任深地工程智能建造与健康运维全国重点实验室副主任、江苏省重要设施防灾减灾创新平台主任;兼任中国岩石力学与工程学会岩石动力学专委会副主任、九三学社江苏省委科技委副主任。主要从事岩石力学与地下工程领域的科研和教学工作,主要研究领域为岩石动力学、裂隙岩体渗流、地下工程稳定控制理论与防灾减灾技术等。
先后主持国家自然基金项目(4项)、科技部仪器设备重点专项、国家重点研发计划专题(4项)、江苏省基础研究计划重点项目、以及矿山、交通、市政和军工领域的企事业单位委托课题累计30多项,并作为执行负责人承担了江苏省重大科研设施预研、双碳科技创新前沿基础、一带一路创新合作等省级重大项目。在行业主流期刊上发表学术论文100多篇,其中第一/通讯作者SCI检索论文50篇,EI检索论文28篇,4篇入选ESI高被引论文,1篇入选F5000论文,总被引3700多次,H-Index为26,出版学术专著3部。授权发明专利60件、软件著作权18件。获得山东省科技进步二等奖(R1)、中国岩石力学与工程学会科技进步一等奖(R1)等科技奖励6项。指导研究生获江苏省优秀专业硕士论文1人次、江苏省土木工程专业优秀毕业生4人次;校级优秀共产党员、共青团员、学生干部、毕业生、毕业论文、学生等校级荣誉18人次。
教育经历
[1] 2005/09 - 2010/07,山东大学,岩土工程专业,博士,导师:李术才教授
[2] 2001/09 - 2005/07,山东大学,水利水电工程专业,学士
科研、学术与访学工作经历
[1] 2018/01至今,中国矿业大学,深部岩土力学与地下工程国家重点实验室,教授
[2] 2019/04至今,陆军工程大学,爆炸冲击防灾减灾国家重点实验室,博士后,合作导师:王明洋教授
[3] 2016/10-2017/10,日本Nagasaki University,访问学者,合作导师:蒋宇静教授
[4] 2015/01-2017/12,中国矿业大学,深部岩土力学与地下工程国家重点实验室,副教授
[5] 2010/08-2014/12,中国矿业大学,力学与建筑工程学院,讲师
主持或参加科研项目(课题)及人才计划项目情况
[1]国家自然科学基金联合重点项目,U24B2040,煤矿复合地质体全时空演化规律与灾害预警基础研究, 2025.01-2028.12, 259万元,主持.
[2]国家自然科学基金面上项目, 52179118,深长隧洞围岩爆生裂隙剪切渗流机制及渗透性能精准评估, 2022.01-2025.12, 75.4万元,主持.
[3]国家自然科学基金面上项目, 51579239,爆破冲击下深部隧洞围岩损伤演化与突水灾变失稳机理, 2016.01-2019.12, 75万元,主持.
[4]江苏省基础研究计划重点项目,BK20243050,地下工程灾害源处置千米级定向钻注机理与动态调控方法, 2024.09-2027.08, 300万元,主持.
[5]国家973计划课题, 2013CB036003,深长隧道突水突泥灾变演化与失稳机理, 2013.01- 2017.08, 554万元,专题题负责人.
[6]国家重点研发计划,2017YFC0603001,千米深井强采动巷道围岩大变形与破坏机理,2017.07-2020.12, 256万元,专题题负责人.
[7]国家自然科学基金青年项目, 51109209,爆破荷载作用下岩石损伤-渗流耦合机理及其在海底隧道中的应用, 2012.01-2014.12, 26万元,主持.
[8]中煤华晋集团有限公司,王家岭矿松软厚煤层大采高综采围岩控制关键技术研究与应用,2024.10-2027.04, 425万元,主持.
[9]中国人民解放军空军勤务学院,浅埋地下硐室衬砌结构××××试验,2020.07-2021.02,51.5万元,主持.
[10]中国人民解放军军事科学院国防工程研究院××××研究所,动静组合××××试验,2020.10-2021.04,39.3万元,主持.
代表性论文(*为通讯作者)
[1]Yu Liyuan,Wu Dongyang*, Su Haijian,et al.Influences of interface roughness and loading direction on tensile behavior of rock-concrete bimaterials under Brazilian test conditions.Rock Mechanics and Rock Engineering,2023.56(8):5861-5883.
[2]Yu Liyuan, Zhang Jing*, Liu Richeng, et al.Estimation of the representative elementary volume of three-dimensional fracture networks based on permeability and trace map analysis: A case study.Engineering Geology, 2022, 309: 106848.
[3]Yu Liyuan, Su Haijian, Jing Hongwen*, et al. Experimental study of the mechanical behavior of sandstone affected by blasting.International Journal of Rock Mechanics and Mining Sciences, 2017, 93:234-241.
[4]Yu Liyuan, Peng Yuxuan*, Li Wei, et al. Experimental and numerical investigation of multiscale mechanical properties of coral aggregate seawater shotcrete.Construction and Building Materials, 2024,450: 138647.
[5]Yu Liyuan, Zhang Tao*, Wu Dongyang, et al. Numericalinvestigationof the effect of grain size‑to‑particle size ratio on the dynamic fracture toughness of granite by using PFC3D‑GBM.Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2022,8:72.
[6]Yu Liyuan,Fu Anqi*, Yin Qian, et al. Dynamic fracturing properties of marble after being subjected to multiple impactloadings.Engineering Fracture Mechanics, 2020, 230: 106988.
[7]Yu Liyuan, Zhang Zhanqun*, Wu Jiangyu, et al. Experimental study on the dynamic fracture mechanical properties of limestone after chemical corrosion.Theoretical and Applied Fracture Mechanics,2020, 108: 102620.
[8]Hu Bowen,Yu Liyuan*, Mi Xianzhen,et al.Comparative analysis of thermodynamic and mechanical responses between underground hydrogen storage and compressed air energy storage in lined rock caverns.International Journal of Mining Science and Technology, 2024,34:531-543.
[9]Li Wei,Yu Liyuan*, Tan Yizhong,et al.Mechanical properties and impact behavior of frozen clay: Insights from static mechanical tests, fly-plate tests, and split-Hopkinson pressure bar analysis.Physics of Fluids,2024,36(5): 057138.
[10]Zhang Tao,Yu Liyuan*, Xu Fei,et al.Influence of mesoscopic defects on the mechanical behaviour of granites based on a three‑ dimensional multilevel force chain network.Rock Mechanics and Rock Engineering, 2024.
[11]Mi Xianzhen,Yu Liyuan*, Zhang Jing,et al.Study on the influence of statistical geometrical characteristics on the permeability tensor of fractured rock masses by the equivalent pipe network method.Computers and Geotechnics, 2024, 165, 105868.
[12] Zhang Tao,Yu Liyuan*, Peng Yuxuan,et al.Effect of the mineral spatial distribution heterogeneity on the tensile strength of granite: Insights from PFC3D-GBM numerical analysis.Journal of Rock Mechanics and Geotechnical Engineering, 2023,15(5): 1144-1160.
[13]WuDongyang, Su Haijian,Yu Liyuan*, et al. Experimental and numerical investigation of dynamic tensile behavior of granite-concrete bimaterials with different rough interfaces.Journal of Building Engineering,2024, 84:108565.
[14]Liu Richeng,Yu Liyuan*, Jiang Yujing, et al. Recent developments on relationships between the equivalent permeability and fractal dimension of two-dimensional rock fracture networks.Journal of Natural Gas Science & Engineering, 2017, 45: 771-785.
[15] Zhang Tao,Yu Liyuan*, Peng Yuxuan, et al. Influence of grain size and basic element size on rock mechanical characteristics: insights from grain‑based numerical analysis.Bulletin of Engineering Geology and the Environment, 2022, 81: 347.
[16]Zhang Jing, Liu Richeng,Yu Liyuan*,et al. Investigations on representative elementary volume and directional permeability of fractal-based fracture networks using polygon sub-models.Fractals, 2020, 28(5): 2050085.
[17]Zhang Tao, Yu Liyuan*, Ju Minghe, et al. Effect of grain size on the dynamic flexural tensile strenth of granite: insight from GBM3D-PFC simulation.International Journal of Geomechanics, 2023,23(5): 04023046.
[18]Peng Yuxuan, Zhang Tao,Yu Liyuan*, et al. Numerical investigation on the effect of intergranular contact bonding strength on the mechanical properties of granite using PFC3D-GBM.International Journal for Numerical and Analytical Methods in Geomechanics, 2023, 47(5): 694-716.
[19]蔚立元,弭宪震,胡波文*,等.内衬式岩洞储氢三维热-流-固耦合模型及洞群运营稳定性分析.中国矿业大学学报,2024(网络首发)
[19]蔚立元,杨瀚清,王晓琳*,等.循环剪切作用下三维粗糙裂隙非线性渗流特性数值模拟研究.岩土力学,2023,44(9):2757-2766.
[20]张涛,蔚立元*,苏海健,等.基于多级力链网络分析的花岗岩压缩特性的矿物尺寸效应研究.岩石力学与工程学报, 2023,42(8):1988-2003.
[21]付安琪,蔚立元*,苏海健,等.循环冲击损伤后大理岩静态断裂力学特性研究.岩石力学与工程学报, 2019, 38(10):2021-2030.
[22]朱子涵,蔚立元*,孟庆彬,等.峰前卸荷损伤大理岩的动静力学特性试验研究.岩石力学与工程学报, 2019, 38(4):747-756.
[23]蔚立元,李光雷,苏海健*,等.高温后无烟煤静动态压缩力学特性研究.岩石力学与工程学报, 2017,36(11): 2712-2719.
[24]蔚立元,李术才,徐帮树,等.水下隧道流固耦合模型试验与数值分析.岩石力学与工程学报, 2011, 30(7):1467-1474.
[25]张站群,蔚立元*,李光雷,等.化学腐蚀后灰岩动态拉伸力学特性试验研究.岩土工程学报, 2020, 42(6):1151-1158.
[26]蔚立元*,朱子涵,孟庆彬,等.循环加卸载损伤大理岩的动力学特性.爆炸与冲击, 2019, 39(8): 083102-1-083102-11.
[27]王超,蔚立元*,杜明瑞,等.碳纳米管增强水泥净浆的动态力学特性.硅酸盐学报, 2021, 49(11): 2486-2493.
[28]蔚立元,韩立军,陈晓鹏,等.含圆孔半平面体的弹性分析及其工程应用.工程力学, 2013,30(7): 167-172.
[29]蔚立元,李术才,郭小红,等.分岔隧道过渡段稳定性研究.中国公路学报, 2011, 24 (01): 89-95.
[30]蔚立元,李术才,徐帮树.青岛小净距海底隧道爆破振动响应研究.土木工程学报, 2010, 43(8): 100-108.
联系方式
通讯地址:江苏省徐州市泉山区大学路1号中国矿业大学深地国重
Email: yuliyuan@cumt.edu.cn
联系电话:15949041625
