头像
更新时间:2024.08.21
总访问量:10

曾玲玲

| 博士 教授 博士生导师

单位:

职务:

研究方向:

办公地址: 屏峰校区土木工程学院

办公电话:

电子邮箱: linglz413@126.com

手机访问
  • 个人简介

    教育及工作经历

    2020.9 ― 至今    浙江工业大学,教授;博士生导师

    2017.6 ― 2020.8   福州大学,教授(破格);博士生导师

    2014.4 ― 2015.4   法国国立路桥大学(Ecole des Ponts ParisTech),博士后

    2013.7 ― 2017.6   福州大学,副教授(破格);博士生导师

    2011.1 ― 2013.6   福州大学,助教、讲师

    2007.9 ― 2011.1   东南大学,获岩土工程专业工学博士

     

    学术兼职

    ²        中国土木工程学会土力学及岩土工程分会软土工程专业委员会委员 

    ²        中国土木工程学会土力学及岩土工程分会环境土工专业委员会委员

    ²        中国土木工程学会土的本构关系及强度理论专业委员会委员

    ²        中国水利学会疏浚与泥处理利用专业委员会委员

    ²        中国地质学会工程地质青年工作委员会委员

    ²        《土木建筑与环境学报》编委

     

    人才计划/项目/奖励

    (1) 2021年入选国家高层次青年人才计划   

    (2)    2020年获福建省青年科技奖

    (3)    2018年获霍英东教育基金会高等院校青年教师基金

     (4)    2016年获福建省杰出青年基金

    (5)    2014年入选福建省青年拔尖创新人才


  • 科研项目

    (1)   国家自然科学基金面上资助项目:疏浚泥负压传递衰减规律与径向固结机理研究No. 51678157),2017-2020年,73万,项目负责人

    (2)    国家自然科学基金面上资助项目:天然沉积土结构渐进损伤机理与定量演变规律研究No. 51478121),2015-2018年,86万,项目负责人

    (3)    国家自然科学基金青年资助项目:考虑固有压缩特性的天然沉积软黏土塑性变形理论与模型(No. 41102168),2012-2014年,25万,项目负责人

    (4)    国家自然科学基金面上资助项目:盐分浸析作用下天然沉积海相黏土劣化性状与定量评价(No. 41372309),2014-2017年,77万,合作单位负责人

    (5)    国家自然科学基金面上资助项目:疏浚泥排泥场空间存储效能控制机理与应用研究(No. 52178361),2022-2026年,58万,项目负责人

    (6)    福建省杰出青年基金:天然沉积土结构屈服演变规律与灵敏度评价理论(2016J06010),2016-042019-0330.0万,项目负责人

    (7)    霍英东教育基金会高等院校青年教师基金:天然沉积结构性土的应力灵敏度与强度灵敏度演化模型(161070),2018-102021-0417.8万项目负责人

    (8)    浙江省属高校基本科研业务费项目:废弃疏浚泥排水机理与堆场有效容积提升技术研究,2020-92022-0930万,项目负责人

    (9)    中国博士后科学基金面上一等资助项目:考虑初始状态和结构性影响的天然沉积土压缩模型研究(2016M590403),2016-62018-5,项目负责人

    (10)    江苏水源公司科技研发项目:基于泥--污染物相互作用的河道底泥污染关键测试技术与应用研究SSY-JS-2020-F-482020-102021-12,项目负责人

    (11)福建建中建设科技股份有限公司科技研发项目:福州市晋安东区河道底泥处理与资源化利用技术研究,2017-72018-12,项目负责人


  • 科研成果

    1Zeng L L, Gao Y F, Hong Z S. Quantitative shear strength–consolidation stress–void ratio interrelations for reconstituted clays. Géotechnique, 2020, publication online, DOI: 10.1680/jgeot.18.p.262

    2Zeng L L, Cai Y Q, Cui Y J, Hong Z S. Hydraulic conductivity of reconstituted clays based on intrinsic compression, Géotechnique, 2020, 70(3): 268-275

    3Zeng, L L, Wang H, Hong Z S*. Hydraulic conductivity of naturally sedimented and reconstituted clays interpreted from consolidation tests. Engineering Geology 272 (2020) 105638.

    4Zeng L L*, Hong Z S, Cui Y J. United void index for normalizing virgin compression of reconstituted clays. Canadian Geotechnical Journal, 2020, 57: 1497–1507.

    5Wang H*, Bian X, Hong Z S, Zeng, L L. Evaluation of vertical superimposed stress in subsoil induced by embankment loads, International Journal of Geomechanics, ASCE, 2019.1.1, 19(1): 1~9.

    6Zeng L L*, Hong Z S, Han J. Experimental investigations on discrepancy in consolidation degrees with deformation and pore pressure variations of natural clays, Applied Clay Science, 2018, 152: 38~43.

    7Zeng L L*, Hong Z S, Tian W B, Shi J W. Settling behavior of clay suspensions produced by dredging activities in China, Marine Georesources & Geotechnology, 2018, 36(1): 30~37.

    8Zeng L L*, Hong Z S, Cui Y J, Martin L. Compression reference of soil structure evaluation with reconstituted clays at different initial water contents, Marine Georesources & Geotechnology, 2018, 36(7): 759-767.

    9Bian X, Zeng L L*, Deng Y F, Li X Z. The role of superabsorbent polymer on strength and microstructure development in cemented dredged clay with high water content, Polymers, 2018, 10, 1069: 1-16.

    10Zeng L L, Cui Y J*, Nathalie C , Jad Z , Gilles A , Jean T. Experimental study on swelling behaviour and microstructure changes of natural stiff teguline clays upon wetting. Canadian Geotechnical Journal, 2017, 54(5): 700–709.

    11Zeng L L*, Hong Z S, GaoY F. One-dimensional compression behaviour of reconstituted clays with and without humic acid. Applied Clay Science, 2017, 144: 45–53.

    12Zeng L L*, Hong Z S , Gao Y F. Practical estimation of compression behaviour of dredged clays with three physical parameters. Engineering Geology, 2017, 217:102-109.

    13Zhang F*, Cui Y J,  Zeng L L, Robinet J C, Conil Nathalie, Talandier, Jean.  Effect of degree of saturation on the unconfined compressive strength of natural stiff clays with consideration of air entry value, Engineering Geology, 2017, 237: 140-148.

    14Zeng L L*, Hong Z S , Wang C and Yang Z Z. Experimental study on physical properties of clays with organic matter soluble and insoluble in water. Applied Clay Science, 2016, 132-133:660-667.

    15Zeng L L*, Hong Z S, Cui Y J. Time-dependent compression behaviour of dredged clays at high water contents in China. Applied Clay Science, 2016, 123: 320-328.

    16Zeng L L, Hong Z S, Cui Y J. On the volumetric strain–time curve patterns of dredged clays during primary consolidation. Géotechnique, 2015, 65(12): 1023-1028.

    17Zeng L L, Hong Z S*. Experimental study of primary consolidation time for structured and destructured clays. Applied Clay Science, 2015, 116-117C: 141-149.

    18Shi J, Qian S, Zeng L L, Bian X. Influence of anisotropic consolidation stress paths on compression behaviour of reconstituted Wenzhou clay. Geotechnique Letters, 2015, 5(4): 275-280.

    19Zeng L L, Hong Z S, Cui Y J*. Determining the virgin compression lines of reconstituted clays at different initial water contents. Canadian Geotechnical Journal, 2015, 52(9): 1408-1415.

    20Hong Z S, Bian X, Cui Y J, GaoY F, Zeng L L. Effect of initial water content on undrained shear behavior of reconstituted clays. Géotechnique. 2013, 63(6): 441–450.

    21Hong Z S, Zeng L L, Cui Y J, Cai Y Q, Cheng L. Compression behaviour of natural and reconstituted clays. Géotechnique, 2012, 62(4): 291-301.

    22Zeng L L,Hong Z S*, Cai Y Q and Han J. Change of hydraulic conductivity during compression of undisturbed and remolded clays. Applied Clay Science, 2011, 51(1-2): 86-93.



链接

更新时间:2024.08.21
总访问量:10