王环玲

发布时间:2021-12-28

王环玲教授,博士生导师,国家级重大人才计划入选者,江苏省“十佳研究生导师团队”核心成员,江苏省高校“青蓝工程”中青年学术带头人,江苏省岩土力学与环境国际合作实验室副主任,科技部教育部重大水电工程多场耦合力学学科创新引智基地学术带头人。中国岩石力学与工程学会岩体数学物理模拟专委会副主任,滑坡与边坡分会常务理事,岩石工程设计方法分会常务理事,中国大坝协会数值模拟专委会委员。获省部级科技进步特等奖1项(排名3),一等奖6项(2项排名1),二等奖2项(1项排名1),主持承担了国家重点研发计划课题、国家自然科学基金等重大科技项目20余项,部分成果在澜沧江、金沙江、雅砻江流域重大水电工程建设和防灾减灾实践中得到重要应用。

教育及工作经历:

2003.3-2006.3,76net必赢 岩土工程 博士

2000.9-2003.6,中国地质大学(武汉) 岩土工程 硕士

1996.9-2000.6,中国地质大学(武汉) 水文地质与工程地质本科

2012.8-2013.8 法国国家科研中心里尔力学研究所(LML, CNRS)和法国里尔科技大学(USTL)访问学者

2014.7-2015.7 加拿大多伦多大学(University of Toronto)工学院高级访问学者

2014.7 破格聘为博士生导师;2015.7 聘为教授(2020年聘为教授三级)

研究方向

1)岩土工程081401

岩石力学与工程

岩石渗流力学基本理论与试验

地质灾害防治与环境保护

多尺度多物理场耦合理论与计算方法

2)水利工程081505

岩土-结构-水流相互作用

工程结构物及其与周围介质相互作用

学术兼职:

江苏省岩土力学与环境国际联合实验室副主任

科技部教育部重大水电工程多场耦合力学学科创新引智基地学术带头人

中国岩石力学与工程学会岩体数学物理模拟专委会副主任

滑坡与边坡分会常务理事

岩石工程设计方法分会常务理事

中国大坝协会数值模拟专委会委员

岩土体多场耦合专委会委员

主讲课程

研究生课程

现代岩土力学(博士生课程)

高等岩石力学(硕士生课程)

Advanced rock and soil mechanics(职工课程)

    本科生课程

岩石力学

工程师文化

研究课题

1. 国家重点研发计划课题(2018YFC1508501):堰塞坝病险情辨别与探测技术,2018.12-2021.12

2. 云南省重大科技专项计划项目(522011912):复杂赋存条件下的红层软岩隧洞工程施工期关键技术研究,2022.1-2024.12

3. 国家重点研发计划专题(2017YFC1501101):水动力型特大滑坡破坏机制与失稳判识模型,2018.01-2021.12

4. 国家自然科学基金(11772116):高渗压作用下岩石渗流流变力学特性的试验与模型研究,2018.01-2021.12

5. 国家自然科学基金(11572110): 各向异性柱状节理岩体渗流应力耦合试验与力学模型研究,2016.01-2019.12

6. 国家自然科学基金(11272113):低渗透岩石渗透特性测试及渗流应力耦合实验研究,2013.01-2017.12

7. 国家自然科学基金(51009052):层状裂隙岩体流-固耦合作用下的变形机理与工程应用研究,2011-2013

8. 江苏省自然科学基金(BK2012809):低渗透岩石流-固耦合机理实验及数值模型研究,2012.01-2014.12

9. 国家自然科学基金(51479049): 岩石渗流应力耦合流变力学实验及本构模型研究,2012-2015

10. 国家十二五科技支撑计划课题(2012BAK03B04):石油储备地下水封洞库工程安全技术,2012.01-2014.12

11. 国家十二五科技支撑计划专题(2013BAB06B01-1):澜沧江流域库群系统安全的主要风险源及其作用机制,2013.01-2015.12

12. 国家重点基础研究发展计划(973)项目:大型水利水电工程高陡边坡全生命周期性能演化与安全控制第四课题,2011.01-2016.12

13. 江苏省教育教改项目,2012-2014

14. 重大工程科技项目(822007616):金沙江白鹤滩水电站库区王家山滑坡稳定性和涌浪三维数值分析研究,2021.9-2022.6

15. 重大工程科技项目:深中通道项目深水深槽凿岩施工技术开发研究,2020.1-2022.12

16. 重大工程科技项目:滇中引水工程项目滇中红层软岩多尺度水岩耦合力学规律及力学特性劣化机理,2021.1-2023.12

17. 重大工程科技项目:滇中引水工程项目滇中红层软岩隧洞围岩变形破坏特征与灾变演化机制,2021.1-2023.12

18. 重大工程科技项目:滇中引水项目红层软岩流变力学特性实验研究及红层软岩隧洞馈控模拟分析,2019-2021

19. 重大工程科技项目:RM水电站可行性研究阶段水库蓄水RS堆积体失稳机理及涌浪传播试验研究(817058916,2020.7-2022.12

20. 重大工程科技项目:特高坝工程坝基渗流应力流变力学与工程安全,2018-2020

21. 重大工程科技项目:白鹤滩水电站高坝坝基渗流应力耦合作用下的长期安全性研究,2014-2016

22. 重大工程科技项目:金沙江白鹤滩水电站各向异性岩石力学特性及模型研究,2009-2013

23. 重大工程科技项目:东岭信滑坡堆积体稳定性分析与防治预警研究,2013-2014

24. 重大工程科技项目:白鹤滩水电站柱状节理玄武岩室内三轴压缩岩石力学试验,2015.6-2017.8

25. 重大工程科技项目:白鹤滩水电站玄武岩室内岩石力学试验,2015.6-2016.1

26. 重大工程科技项目:澜沧江糯扎渡水电站枢纽区右岸下游护岸泄洪雾雨区边坡研究,2006-2007

27. 揭榜挂帅专题:雅下重大水电开发滑坡灾害链及防灾减灾研究,2021.1-2023.12

28. 重大工程科技项目:面向YX水电建设的高位高危滑坡灾害链分析及数值模拟研究, 2022.3-2023.12

29. 重大工程科技项目:西藏LCBDa水电站枢纽区工程边坡数值计算及模型研究,2023.3-2024.12

论著

  1.王环玲,徐卫亚.致密岩石渗透测试技术与渗流力学特性,科学出版社,2015

2.徐卫亚, 张超, 王如宾, 王环玲, 赵海斌. 大型地下水封洞库围岩流变力学与长期安全性分析,科学出版社,2016

部分论文

1. Wang, HL., Jiang, Z., Xu, W., Wang, R., & Xie, W. (2022). Physical model test on deformation and failure mechanism of deposit landslide under gradient rainfall. Bulletin of Engineering Geology and the Environment, 81(1), 1-14.doi.org/10.1007/s10064-021-02566-y

2. Xiao Qu, Huanling Wang*, Wei‑chau Xie, Hangsheng Ma. Experimental investigation on dynamic compressive mechanical properties of weathered granite and statistical damage constitutive model. Bulletin of Engineering Geology and the Environment (2023) 82:313, https://doi.org/10.1007/s10064-023-03326-w

3. S. Liu, H. Wang*, X. Qu, and Z. Cheng, “Experimental Investigation and Energy Evolution of Brittle Limestone Subjected to Multistage Cyclic Loading,” Geotechnical Testing Journal, 2023, https://doi.org/10.1520/GTJ20220127

4. S. Liu, H. Wang*, X. Qu, Bing Pan,Wei-chau Xie. Experimental Investigation on the Effect of Strain Rate on Brittle Limestone in Postearthquake Landslide Area. Pure and Applied Geophysics, 2023, https://doi.org/10.1007/s00024-023-03294-y

5. Zhang T, Xu WY, Wang HL, Wang RB, Yan L, Xu JR (2023) Anisotropic Strength, Deformability, and Failure Behavior of Artificial Columnar Jointed Rock Masses under Triaxial Compression. Journal of Materials in Civil Engineering 35(3) https://doi.org/10.1061/(ASCE)MT.1943-14

6. Huanling Wang*, Shiqi Liu*, Xiao Qu, Ruibiao Zhan, Zengping Liao.Field investigations on rock fragmentation under deep water through fractal theory. Measurement199 (2022) 111521

7. Zhang T, Xu WY, Wang HL*, Wang RB, Shi AC (2022) Experimental Investigations on short-term and creep anisotropic mechanical behavior of artificial columnar jointed rock masses. Rock Mechanics and Rock Engineering 55:5393-5413. https://doi.org/10.1007/s00603-022-02880-1

8. Zhang T, Xu WY, Wang HL*, Wang RB, Yan L, Shi AC (2022) Anisotropic mechanical characteristics and energy evolution of artificial columnar jointed rock masses subjected to multi-level cyclic loading. International Journal of Fatigue 165https://doi.org/10.1016/j.ijfatigue.2022.107215

9. Tao Zhang , Weiya Xu , Huanling Wang *, RuBin Wang , Long Yana, MingTao Hu. Anisotropic mechanical behaviour of columnar jointed rock masses subjected to cyclic loading: An experimental investigation. International Journal of Rock Mechanics and Mining Sciences. 148 (2021) 104954

10. Wang HL*; Liu SQ; Xu WY; Yan L; Xie WC. (2020). Numerical investigation on the sliding process and deposit feature of an earthquake-induced landslide: a case study. Landslides. 17(9):2671-2682. Doi: 10.1007/s10346-020-01446-y

11. Jiang ZH; Wang HL*; Xie WC. (2021). Deformation mechanism of deposit landslide induced by fluctuations of reservoir water level based on physical model tests. Environmental Earth Sciences. 80(11). Doi: 10.1007/s12665-021-09673-9

12. Wang Z; Wang HL*; Xu WY. (2021). Effect of rotated anisotropy of soil shear strength on three-dimensional slope stability: a probabilistic analysis. Bulletin of Engineering Geology and the Environment. 80(8):6527-6538. Doi: 10.1007/s10064-021-02336-w

13. Cheng ZC ; Wang HL*; Xu WY ; Yan L. (2021). Numerical investigation of the flow characteristics and permeability of 2D irregular columnar jointed rock masses. Engineering Computations. 38(10):4091-4110. Doi: 10.1108/EC-10-2020-0603

14. Wang Z; Wang HL*; Xu WY; Xie WC. (2021). Slope stability analysis considering the rotated anisotropy in soil properties. Engineering Computations. 58(9):1365-1378. Doi: 10.1139/cgj-2019-0611

15. Zhang TXu WYWang HL*Wang RBYan LHu MT. (2021). Anisotropic mechanical behaviour of columnar jointed rock masses subjected to cyclic loading: An experimental investigation. International Journal of Rock Mechanics And Mining Sciences. DOI: 10.1016/j.ijrmms.2021.104954

16. Xiang ZP; Wang HL*; Xu WY;  Xie WC. (2020). Experimental Study on Hydro-mechanical Behaviour of Anisotropic Columnar Jointed Rock-Like Specimens. Rock Mechanics and Rock Engineering. 53(12):5781-5794. Doi: 10.1007/s00603-020-02245-6

17. Liu SQ; Wang HL*; Xu WY; Cheng ZC; Xiang ZP; Xie WC. (2020). Numerical Investigation of the Influence of Rock Characteristics on the Soil-Rock Mixture (SRM) Slopes Stability. KSCE Journal of Civil Engineering. 24(11):3247-3256. Doi: 10.1007/s12205-020-0034-1

18.  Qing xiang Meng; Huangling Wang*; Ming Cai; Weiya Xu; Xiaoying Zhuang; Timon Rabczuk. (2020). Three-dimensional mesoscale computational modeling of soil-rock mixtures with concave particles. Engineering Geology. 277. Doi.org/10.1016/j.enggeo.2020.105802

19. Huanling Wang*, Kai Zhao, Xiao Qu, Jianrong Xu, Ming Cai. Hydro-mechanical properties of rock-like specimens with pre-existing intermittent joints. European Journal of Environmental and Civil Engineering. 2020. DOI: 10.1080/19648189.2020.1763853

20. Jiang ZH; Wang HL*; Xu JR; Chen HJ; Xie WC. (2020). Variation of permeability of natural filled jointed rock under repeated loading and unloading conditions. European Journal of Environmental and Civil Engineering, 1-13.

21. Huang, W; Wang, HL*; Zhang, T; He, MJ; Yan, L. (2020). Hydraulic pressure effect on mechanical properties and permeabilities of layered rock mass: an experimental study. European Journal of Environmental and Civil Engineering, DOI: 10.1080/19648189.2020.1763844.

22. Meng QX; Wang HL*; Xu WY; Chen YL. (2019). Numerical homogenization study on the effects of columnar jointed structure on the mechanical properties of rock mass. International Journal of Rock Mechanics and Mining Sciences, 124:104127.

23. Meng QX; Wang HL*; Xu WY; Cai M; Xu JR; Zhang Q. (2019). Multiscale strength reduction method for heterogeneous slope using hierarchical FEM/DEM modeling. Computers and Geotechnics, 115:103164.

24. Susheng Wang, Huanling Wang*, Weiya Xu, Ming Cai. (2019). A coupled elasto-plastic damage model for fine-grained sandstone under triaxial compression and lateral extension loading conditions, European Journal of Environmental and Civil Engineering, (3), 1-17.

25. Huanling Wang* , Weiya Xu, Cai Ming, Zhipeng Xiang, Kong Qian, Gas permeability and porosity evolution of a porous sandstone under repeated loading and unloading conditions, Rock Mechanics & Rock Engineering, 2017, 50(8), 2071-2083.

26. H.L.Wang*; W.Y.Xu; C. J. Jia,;M.Cai; Q. X. Meng(2016). Experimental Research on  Permeability Evolution with  Microcrack Development in Sandstone under Different Fluid Pressures, Journal of Geotechnical and Geoenvironmental Engineering, DOI:10.1061(ASCE) GT.1943-5606.0001462.142(6)

27. Huanling Wang *, Weiya Xu, Zaobao Liu, Zhiming Chao, Qingxiang Meng, Dependency of hydromechanical properties of monzonitic granite on confining pressure and fluid pressure under compression. International Journal of Modern Physics B, 2016, 30(16):1650086. 2016, 30(16), 1-15

28. Qingxiang Meng, Huanling Wang*, Weiya Xu, Qiang Zhang. A coupling method incorporating digital image processing and discrete element method for modeling of geomaterials. Engineering Computations, 2017, 35(1), 46-54.

29. Huanling Wang*Weiya Xu, Ming Cai, Mechanical properties of altered granite gneiss considering time effect, Geomechanics and Geoengineering, 2017, 12(3), 215-219.

30. Meng Q X, Wang H L*, Xu W Y, et al. A numerical homogenization study of the elastic property of a soil-rock mixture using random mesostructure generation. Computers & Geotechnics, 2018, 98(6):48-57

31. H. L. Wang*; W. Y. Xu; M. Cai; J. Zuo.An Experimental Study on the Slippage Effect of Gas Flow in a Compact Rock. Transport in Porous Media.DOI 10.1007/ s11242- 016- 0635-9

32. Wang Huanling*Xu WeiyaZuo JingCompact rock material gas permeability propertiesPhysica B:Physics of Condensed Matter2014449(6)10-18

33. Wang huanling*xu weiyashao jianfuExperimental Researches on Hydro-Mechanical Properties of Altered Rock Under Confining PressuresRock Mechanics and Rock Engineering.2014,(47)485-493

34. wang huanling* xu weiyaPermeability Evolution Laws and Equations during the Course of Deformation and Failure of Brittle RockJournal of Engineering Mechanics2013,139(11)1621-1626

35. WANG Huan-ling*, XU Wei-yaZHU Feng.The mechanical response of piles with consideration of pile-soil interactions under a periodic wave pressure. Journal of Hydrodynamics2014266):921-930  

36. Wang huanling*,Weiya Xu,Jianfu Shao,Frederic Skoczylas. The gas permeability properties of low-permeability rock in the process of triaxial compression test. Materials Letters, 2014, 1161: 386-388

37. Wang huanling*, xu weiya. Stability of Liangshuijing landslide under variation water levels of Three Gorges Reservoir, European Journal of Environmental and Civil Engineering, 2013, 17(1): 158-173

38. Wang Huan-ling* , Chu Wei-jiangHe Miao. Anisotropic permeability evolution model of rock in the process of deformation and failureJournal of Hydrodynamics2012241):25-31

39. Wang, S. N.Shi, C. Xu, W. Y.Wang, H. L.Zhu, Q. Z. Numerical direct shear tests for outwash deposits with random structure and composition Granular Matter2014165):771-783

40. Huan-ling Wang*, Wei-ya Xu, Long Yan, Qing-xiang Meng, Ru-bin Wang, Hai-bin Zhao, Wei-chau Xie. Investigation on time-dependent behaviour and long-term stability of underground water-sealed cavern. European Journal of Environmental and Civil Engineering, 19, 119–139, 2015

41. Lin, Zhinan, Xu, Weiya, Wang, Wei , Zhang, JiuchangWang,HuanlingWang, Rubin. Experimental Study on Hydraulic and Macro-Mechanical Property of a Mortar under Heating and Cooling TreatmentJournal of Advanced Concrete Technology2016.5.01145):261~270

42. J. C. Zhang, W. Y. Xu, H. L. Wang, R. B. Wang and Q. X. Meng. 2016. Testing and modeling of the mechanical behavior of dolomite in the Wudongde hydropower plant. Geomechanics and Geoengineering: An International Journal. DOI: 10.1080/17486025.2016.1151557

43. J.C. Zhang, W.Y. Xu, H.L. Wang, R.B. Wang, Q.X. Meng, S.W. Du. A coupled elastoplastic damage model for brittle rocks and its application in modelling underground excavation, International Journal of Rock Mechanics and Mining Sciences, http://dx.doi.org/10.1016/j.ijrmms.2015.11.011

44. W.Y. Xu, Q. Zhang, R.B. Wang, H.L. Wang, R.K. Wang, W.C. Xie. Mechanism of continuous movement and long-term safety analysis of Baitieba landslide based on field monitoring data and numerical simulation. European Journal of Environmental and Civil Engineering, 19, s140–s154, 2015.

45. Q.-X. Meng, H.-L. Wang*, W.-Y. Xu, W.-C. Xie, R.-B. Wang, J.-C. Zhang. Robust equivalent tunnelling Mohr–Coulomb strength parameters for generalised Hoek–Brown media. European Journal of Environmental and Civil Engineering, 2015, http://dx.doi.org/10.1080/19648189.2015.1084380.

46. Yan L, Meng Q, Xu W Y, Wang H L, Zhang Q. A numerical method for analysing the permeability of heterogeneous geomaterials based on digital image processing. Journal of Zhejiang Universityence A, 2017, 18(2):124-137.

47. Wang huanling*Xu weiyaRelationship Between Permeability and Strain of Sandstone During the Process of Deformation and Failure, Geotech Geol Eng2013,311):347-353.I

48. 王环玲*, 徐卫亚,左婧,邵建富,贾朝军,基于气渗的低渗透岩石渗透率与孔隙率演化规律研究,水利学报,2015.1.146(1)58~66

49. 王环玲*,徐卫亚,巢志明,孔茜,致密岩石气体渗流滑脱效应试验研究,岩土工程学报,2015.11.01,(05):777-785

50. 贾朝军,王环玲*,徐卫亚,左靖,Skoczylas F,地下水封洞库围岩气体渗透特性及滑脱效应研究,工程力学,2015.8.0132(8)50-58

51. 孔茜,王环玲*,徐卫亚,循环加卸载作用下砂岩孔隙度与渗透率演化规律试验研究,岩土工程学报,2015.01.0137(10)1893-1901

52. 巢志明,王环玲*,徐卫亚,贾朝军,夏季,柱状节理岩体渗透性模型试验研究,岩土工程学报,201608):1407-1416

53. 赵恺, 王环玲* ,徐卫亚,夏季.贯通充填裂隙类岩石渗流特性试验研究,岩土工程学报, 201739(6), 1130-1136

54. 巢志明, 王环玲*, 徐卫亚, 杨兰兰, 赵恺.不同饱和度砂岩渗透率、孔隙度随应力变化规律研究. 岩石力学与工程学报, 2017, 36(3), 665-680.

55. 巢志明, 王环玲*, 徐卫亚,贾朝军,方应东. 不同含水饱和度低渗透岩石气体滑脱效应研究. 岩土工程学报, 2017, 39(12):2287-2295.

56. 巢志明, 王环玲*, 徐卫亚, 吉华,赵恺.循环加卸载下柱状节理材料渗透率和孔隙度演化规律研究. 岩石力学与工程学报,2017,36(1):124-141.

57. 巢志明,王环玲*,徐卫亚,贾朝军,赵 恺.一种快速制备不同含水饱和度岩石试样的方法,岩土力学,2108,3:

58. 王环玲, 徐卫亚, 童富国. 泄洪雾雨作用下边坡饱和非饱和非稳定渗流研究. 岩土力学, 2006,(27): 331-336

59. Zhipeng XiangHuanling Wang (#)Weiya XuLiangquan Liand Ming Cai. Mechanical Behavior of Rock-Like Specimens with Hidden Smooth Joints under Triaxial Compression [J]. Journal of Materials in Civil Engineering,2019,31(7),140-150.

60. Lanlan Yang, Weiya Xu*, Qingxiang Meng, Wei-Chau Xie, Huanling Wang, Mengcheng Sun. Numerical Determination of RVE for Heterogeneous Geomaterials Based on Digital Image Processing technology. Processes, 2019, 7(6): 346

61. Wang S, Wang H, Xu W, et al. Investigation on mechanical behaviour of dacite under loading and unloading conditions. Géotechnique Letters, 2019: 1-6.

62. Liu, S., Wang, H. (#), Xu, W., & Xiang, Z. (2019). The influence of water saturation and confining pressure to gas porosity and permeability of sandstone. Environmental earth sciences, 78(6), 182-192

63. 王环玲*, 沙聪, . 基于颗粒离散元的土石混合体强度影响研究[J]. 土木工程学报, 2020,53(9),106-114.

64. 王环玲*,沙聪,孟庆祥.考虑孔隙率和不均匀系数的土石混合体颗粒流分析[J].公司学报(自然科学版),2019,47(03):251-258.

65. 柯志强,王环玲*,徐卫亚,林志南,吉华.含横向节理的柱状节理岩体力学特性试验研究[J].岩土力学,2019,40(02):660-667.

66. 王环玲*,屈晓,王如宾,刘士奇. 堰塞坝堆积演化过程及开发利用研究进展[J].中国地质灾害与防治学报,2021,32(1), 11.

近期授权国家发明专利:

1. 一种致密岩石材料气体渗透率测试装置及测算方法ZL 2013 1 0085675.62014

2. 用于层状裂隙灰岩试验的裂纹系统试件的制备方法ZL 2012 1 0534517.X2014

3. 柱状节理岩体渗透张量测试方法及各向异性定量评估方法ZL 201510737468.3

4. 一种确定裂隙岩体表征单元体积的方法 ZL 201511022607.02017

5. 一种快速制备不同含水饱和度试样的方法ZL 201510364803.X2017

6. 确定裂隙岩体不同方向渗透率对孔隙度敏感程度的方法ZL 201610064275.02018

7. 一种岩石气体渗透测定装置及测定方法ZL 2012 1 0590766.02015

8. 一种岩土体材料快速矢量化方法ZL 201510014421.42017

9. 一种柱状节理岩体边坡锚索支护方法 ZL 201510747404.12017

10. 一种原位柱状节理岩石的试验模型制备方法ZL 201510060098.42017

11. 一种等效结点荷载的通用精确积分计算方法ZL 201510020173.42017

12. 一种含隐节理的类岩石试样制备装置及制备方法  ZL201710139612.22019

13. 一种致密无填充裂隙岩体试样的制备方法 ZL201710053540.X2019

14. 确定岩石试验中产生滑脱效应的隐节理密度阈值的方法ZL201710050242.52019

15. 确定裂隙岩体不同方向渗透率对孔隙度敏感程度的方法ZL 201610064275.02018

16. 柱状节理岩体渗透张量测试方法及各向异性定量评估方法ZL201510737468.32018

17.  一种定量确定裂隙岩体渗透各向异性的方法ZL 201610065036.72018

18. 一种含充填隐节理的柱状节理岩体试样的制备方法ZL 201511023783.62018

19. 一种基于3D打印技术的非贯通裂隙岩体试样的制备方法ZL 201511019619.82018

20. 一种含无充填隐节理的柱状节理岩体试样的制备方法ZL 201511016772.52018

21. 一种基于3D打印技术的贯通裂隙岩体试样的制备方法ZL 201511018137.02018

22. 一种基于盲信息的堆积体滑坡安全评价方法ZL 201610256635.72018

23. 一种含隐节理的类岩石试样制备装置及制备方法ZL201710139612.2,2019

24. 一种致密无填充裂隙岩体试样的制备方法ZL201710053540.X,2019

25. 确定岩石试验中产生滑脱效应的隐节理密度阈值的方法ZL201710050242.5, 2019

26. 一种咬合节理岩体周期性结构模型的生成方法ZL201710650965.9, 2019

27. 一种确定岩石相对渗透率的方法ZL201810338314.0,2019

28. 一种确定岩石有效应力系数的方法ZL201710403114.4,2020

29. 确定充填节理岩石压密所需最小循环加卸载次数的方法ZL201810323908.4, 2019

30. 岩石渗流应力耦合过程中渗透率与孔隙率关系的确定方法ZL201910602768.92020

31. 一种无已知底滑面的滑坡滑动过程模拟方法ZL201910168033X

32. 一种在块体离散元中确定柱状节理岩石节理刚度的方法ZL201910661442.3

33. 一种岩石流变加载条件下多气体渗流测试装置及测试方法ZL201911085405.9

34. 一种测试滑坡稳定性的物理模型试验装置及测试方法ZL201910681406.3

35. 一种不规则柱状节理类岩石试样的制备方法 ZL201910602761.7

36. 一种基于粒子群优化算法的滑坡区间稳定性分析方法ZL201910840635.5

37. 模拟边坡地震动力失稳的振动台试验模型箱及试验方法ZL20191067536.2

38. 一种低渗透多孔介质材料的流固耦合模型构建方法ZL201810874858.9

39. 一种确定高海拔寒区岩石冻融损伤程度的方法ZL201810323991.5

40. 一种基于网格化的颗粒模型损伤表征方法ZL 202010205959.4

41. 一种基于矿物晶粒定向发育的各向异性岩石建模方法ZL202010205954.1

42. 一种考虑晶粒咬合的各向异性岩石建模方法ZL202010205967.9

43. 一种基于多源声呐定位的水下滑坡体变形监测装置和方法ZL202010610338.4

44. 一种滑坡涌浪模型试验装置及滑坡涌浪测试方法ZL202010534375.1

45. 一种环保型海底礁石清理施工工艺ZLZL 202010608442.X

46. 一种凿岩棒凿击速度可控的水下岩石清理平台及清理方法ZL202010608491.3

47. 一种分段式中空排水预应力让压锚杆及其支护方法ZL202010768397.4

48. 确定库区滑坡稳定状态下的库水位下降速率阈值的方法ZL202010533934.7

49. 一种基于ARIMA-GC=SVR的高拱坝谷幅变形预测分析方法ZL202010610261.0

50. 一种基于GRU的地下工程支护智能监测预警系统及方法ZL 202010553299.9

51. 河道型水库三维滑坡涌浪试验正态物理模型ZL202210105273.7

52. 一种再现堰塞坝堆积特性的数值模拟方法ZL20201 0586131.8

53. 一种优化滑坡条间推力的去条块Janbu条分法ZL 2020 1 0639292.9

 

近期获批软件著作权:

1. 各向异性岩体三维渗流应力耦合分析软件V1.02014SR0136222014 

2. 工程岩体三维后处理可视化软件V1.0 2014SR0136252014

3. 三维非线性有限元分析软件V1.02014SR0136272014 

4. 各向异性岩体饱和非饱和三维渗流分析软件V1.02014SR0136312014 

5. 工程岩体三维程序建模软件V1.02014SR0136232014

6. 基于水平集法的极限平衡有限元边坡稳定性分析软件,2015SR2154792015

7. 弹塑性损伤本构开发软件V1.02017SR7232562017

8. 土石混合体颗粒模型转化程序V1.0 2019SR11587572019

9. 基于粒子群优化算法的区间极限平衡边坡稳定性分析软件V1.0, 2019SR06186032019

10.松动碎裂岩体连续-非连续耦合多尺度数值仿真软件 2019

11.岩石真三轴力学试验数据处理及强度准则软件 2019

12. 考虑岩石局部化效应本构模型开发软件V1.0 2019

13.土石混合体颗粒模型转化程序V1.0 2019SR11587572019

14.基于优化算法和区间理论的滑坡有限元极限平衡分析软件[简称POS_FLEM]1.0,  2020SR0970591 2019.

15.块体离散元位移反分析软件V1.02020SR0975562020

16.抗滑桩最优参数筛选程序V1.02020SR12615072020

 

奖励与荣誉

2022年,国家级重大人才计划入选者

2022年,岩石力学与防灾减灾研究生导师团队,获评为江苏省“十佳研究生导师团队”

2022年,滑坡致灾力学机理及灾害链演化研究与工程应用,水力发电科学技术奖,一等奖

2022年,依托高水平国际合作与交流,岩石力学与防灾减灾高质量人才培养模式与实践,76net必赢教学成果一等奖

2020年,依托国家重大工程建设,高质量拔尖创新工程人才培养模式与实践,76net必赢教学成果一等奖

2019年,柱状节理玄武岩坝基松弛控制关键技术及在特高拱坝工程中的应用,中国大坝工程学会科学技术奖,一等奖

2018工程岩石渗流力学及应用江苏省科学技术奖二等奖

2018,各向异性岩石力学特性力学模型及工程应用,水力发电科学技术奖,一等奖

2016年,岩石渗流-应力-流变耦合理论研究与工程应用,水力发电科学技术奖,一等奖

2013年,水利水电工程大型堆积体特性及失稳防控研究,水力发电科学技术奖,特等奖

2013年,多场耦合多尺度岩石力学研究,江苏省科学技术奖,二等奖

2010年,大型水电工程岩石高边坡工程安全理论研究与工程应用,大禹水利科学技术进步奖,一等奖

201076net必赢教学成果奖二等奖

2014年,江苏省高校“青蓝工程”优秀青年骨干教师

2019年,江苏省高校“青蓝工程”中青年学术带头人

联系方式

76net必赢西康路校区科学馆1009

E-mailwanghuanling@hhu.edu.cn

电话:025-83787379