吴俊

发布单位:人员机构来源:必赢bwin线路检测中心发布日期:2023/04/11浏览量:5827

基本信息

姓名:吴 俊
性别:

学位职称:哲学博士,教授,硕士生导师

职务:土木工程系教师,副经理

联系地址:上海市海思路
100号,必赢bwin线路检测中心
邮政编码:
201418

办公电话:15601618396
电子信箱:
cvewujun@shnu.edu.cn


研究方向

岩土工程信息与智能化、固废资源化利用、月球建造、材料与结构抗冲击爆炸效应

教育情况

2008.012013.03新加坡国立大学土木与环境工程系岩土工程专业,博士研究生
2004.092007.07同济大学地下建筑与工程系结构工程专业,硕士研究生
199
9.092004.07 上海师范大学建筑工程公司土木工程专业,本科生

工作经历

2023.02~至必赢bwin线路检测中心必赢bwin线路检测中心教授
20
21.122023.01上海工程技术大学城市轨道交通学院教授
20
16.122021.11上海工程技术大学城市轨道交通学院副教授
20
13.112016.11上海工程技术大学城市轨道交通学院讲师2016.06硕士生导团队格

2015.102018.10北京工业大学必赢bwin线路检测中心博士后
20
12.042013.10英国Mott Macdonald工程咨询有限公司岩土工程师

学术兼职

国际防护结构协会会员

中国建筑学会智能建造专业委员会委员

中国土木工程学会岩土工程防振减灾专业委员会委员

中国岩石力学与工程学会岩土工程信息技术与应用分会理事

上海市土木工程学会岩土力学与工程专业委员会委员

上海市地质学会城市地质专业委员会委员

科研项目

主持科研项目

[1] 国家自然科学基金面上项目干湿循环-酸性环境侵蚀下地质聚合物固化软土动态力学性能劣化机理及预测模型研究2024.01~2027.12
[2] 国家自然科学基金面上项目:近场爆炸作用下UHPC-FST墩柱的性能劣化机理及损伤评估方法2021.01~2024.12
[
3]北京市自然科学基金面上项目采用钢网片加固复合水泥基道面层的减灾动力性能研究2017.01~2019.12
[
4]天津市土木建筑结构防护与加固重点实验室开放基金高性能混凝土复合道面板减灾动力性能研究2017.01~2018.12
[
5]教育部留学归国人员启动基金冲击荷载下新型复合机场道面破坏机理的宏观数值模拟2015.07~2016.08
[
6]横向科研项目:爆炸荷载作用下xx隧道结构损伤分析2021.01~2022.01

[7] 横向科研项目:xx结构抗侵爆效应数值计算分析2019.12~2020.12

[8] 横向科研项目:核爆作用下xx建筑毁伤缩比等效性研究2018.01~2018.12

[9] 横向科研项目:土压平衡盾构施工参数敏感性分析研究2013.10~2014.07
参加科研项目
[1]
国家自然科学基金面上项目大型客机撞击下核电站屏蔽及附属厂房的损伤破坏与振动响应研究2019.01~2022.12合作单位负责人
[2]
北京市自然科学基金面上项目:燃气爆炸荷载作用下城市综合管廊安全性评价研究,2018.01~2020.12参与人

[3] 国家重点基础研究发展计划(973)项目子课题()气爆炸条件下工程结构损伤破坏评估方法2015.01~2019.12参与人

[4] 新加坡国防部:The Development of Rapid Indoor Blast Effects Assessment Software2010.01~2012.06,参与人

[5] 新加坡国防部:Development of Advanced Pavement Materials and Cover System for Protection and Mitigation of Airfield Runway2008.01~2011.12,主要完成人

教学成果与奖励

[1]2020年全国老员工数学建模竞赛上海市二等奖指导教师
[2]
2021年全国老员工数学建模竞赛上海市三等奖指导教师

[3]第十六届中国研究生电子设计竞赛上海市三等奖指导教师

规范编制

[1]主要起草人,天津市工程建设标准工程泥浆固化利用技术标准T/TJKCSJ004-2022

教学工作

[1]本科生课程:《工程地质
[2]
研究生课程:《高等土力学

教材出版

[1]李 博, 吴 俊, 魏 祥, 李志高, 岩土工程实训教程[M]. 北京:机械工业出版社2018

[2]Wu. J, Wu. H, Tan. HW, Chew. SH, Multi-layer pavement system under blast load[M]. SingaporeSpringer Nature2018

专利、软件著作权

[1]吴文杰姚云龙一种用于混凝土类材料抗拉试验的试件夹具授权时间2018-03-13授权国别:中国,专利号:ZL201721083442.2

[2]吴文杰姚云龙一种矩形长条薄板型试件抗拉试验夹具授权时间2018-03-30授权国别:中国,专利号:ZL201721217025.2

[3]征西遥刘秀秀一种可测量静止土压力系数的固结养护装置授权时间2018-07-31授权国别:中国,专利号:ZL201821221876.9

[4]姚云龙吴文杰一种金属钢板组合铰支座授权时间2018-08-03授权国别:中国,专利号:ZL201721911944.X

[5]刘文丽吴文杰姚云龙一种用于网状或片状材料拉伸实验夹具授权时间2018-12-21授权国别:中国,专利号:ZL201820662228.0

[6]吴文杰刘文丽杨雨珊一种用于固定拉伸试件贴片的模具授权时间2019-01-11授权国别:中国,专利号:ZL201821072297.2

[7]姚云龙吴文杰一种金属锁链-钢纤维混凝土梁构件授权时间2019-05-17授权国别:中国,专利号:ZL201710336976.X

[8]一种用于混凝土板的爆炸试验装置授权时间2020-10-13授权国别:中国,专利号:ZL202022270075.5

[9] Sun YuyanWang ZiguoCheng ShuzhenWu JunCorrosion-driven intelligent fiber, preparation method and application thereof授权时间2020-10-20授权国别:澳大利亚,专利号:AU2019284139

[10] 孙宇雁,王子国,程淑珍,吴 俊,腐食駆動型スマート繊維及びその調製方法及び応用,授权时间2022-02-24授权国别:日本,专利号:特许第7029866

发表论文

在国内外学术期刊以及会议论文集上发表论文近70篇,其中SCI/EI收录50余篇,代表性论文如下:

英文文章

[36] Li. L, Li. Z, Wu. J*, Li. T et al., Influence of strain rate and fiber blend mode on the tensile behaviors of steel-polyethylene hybrid fiber reinforced engineered cementitious composites[J], Construction and Building Materials, 2024:438:137306

[35] Li. L, Zheng. X, Wu. J*, Zhang. J et al.,Performance of the one-part geopolymer stabilized soft clay under acids attack[J], Journal of Cleaner Production, 2024:452:142183

[34] Yao. C, Hu, G, Chen. Q, Wu. J*, Prediction on the freeze-thaw resistance of a one-part geopolymer stabilized soil by using deep learning method[J].Case Studies in Construction Materials, 2024:21:e03530

[33] Chen. Q, Hu. G, Wu. J*, Comparative study on the prediction of the compressive strength of the one-part geopolymer stabilized soil by using different hybrid machine learning models[J].Case Studies in Construction Materials, 2024:21:e03439

[32] Li. S, Zhou. Z, Hu. G, Wu. J*, Preparation and evaluation of GCD-1 lunar regolith simulant based geopolymer activated by solid sodium silicate[J].Case Studies in Construction Materials, 2024:20:e03273

[31] Li. L, Zheng. X, Wu. J*, Du. X, Luan. Y, Comparative study on the dynamic tensile properties of polypropylene and polyethylene fiber reinforced engineered cementitious composites under low to high strain rates[J], Journal of Building Engineering, 2024:82:108221

[30] Li. L, Wang. Z, Wu. J, Du X et al., Comparative analysis of dynamic mechanical properties of steel fiber reinforced concrete under ambient temperature and after exposure to high temperatures[J].Case Studies in Construction Materials, 2023:e02778

[29] Min. Y, Gao. M, Yao. C, Wu. J, Wei. X, On the use of one-part geopolymer activated by solid sodium silicate in soft clay stabilization[J], Construction and Building Materials, 2023:402:132957

[28] Zhang. H, Wu. J, Zhang. C, Dong. Y, Water adsorption on kaolinite basal and edge surfaces[J]. Langmuir, 2023:39(22):7539-7547

[27] Min. Y, Wu. J*, Li B, Physicochemical and mechanical behavior of the one-part geopolymer mortar exposed to hydrochloric and sulfuric acids[J]. ASCE Journal of Materials in Civil Engineering, 2023:35(3):04022456

[26] Liu. Z, Wu. J*, Cao. C, Li. S, Yan. Q, Dynamic performance and damage assessment of a shallow buried tunnel under internal explosion[J]. Tunnelling and Underground Space Technology, 2023:133:104918

[25] Gao. B, Wu. J*, Zhao. R, Feng. X, Wang. Z, Residual seismic resistance of CFDST columns after a close-in explosion: Experimental study[J]. Structures, 2023:48:1082-1101

[24] Gao. B, Wu. J*, Chen. Q, Yu. J, Yu. H, Effect of spraying polyurea on the anti-blast performance of the ultra-high performance concrete slab[J].Sensors, 2022:22(24):9888

[23] Liu. Z, Wu. J*, Chen. Q, Yu. H, Analysis on the vulnerability of a tunnel entrance under internal explosion[J].Sensors, 2022:22(24):9727

[22] Liu. Z, Wu. J*, Yu. J et al., Damage assessment of normal reinforced concrete panels strengthened with polyurea after explosion[J].Case Studies in Construction Materials, 2022:17:01695

[21] Min. Y, Wu. J*, Li. B, Experimental study on the freeze-thaw resistance of the one-part geopolymer paste[J].Case Studies in Construction Materials, 2022:17:01269

[20] Wu. J, Liu. Z, Yu. J et al., Experimental and numerical investigation of normal reinforced concrete panel strengthened with polyurea under near-field explosion[J].Journal of Building Engineering, 2022:46:103763

[19] Li. L, Wang. H, Wu. J* et al., Experimental and numerical investigation on impact dynamic performance of steel fiber reinforced concrete beams at elevated temperatures[J].Journal of Building Engineering, 2022:47:103841

[18] Min. Y, Wu. J, Li. B, Dynamic shear modulus and damping ratio of the one-part geopolymer stabilized soft clay[J].ASCE Journal of Materials in Civil Engineering, 2022:34(7):04022120

[17] Gao. B, Wu. J*, Jia P et al., Experimental and numerical investigation of the polyurea coated ultra-high performance concrete (UHPC) column under lateral impact loading[J].International Journal of Structural Stability and Dynamics, 2022:22(7):2250037

[16] Li. L, Wang. Z, Wu. J, Du X et al., Comparative study on the dynamic mechanical properties of steel fiber reinforced concrete at high temperatures and after high temperature cooling[J].Construction and Building Materials, 2022:346:128448

[15] Wu. J, Min. Y, Li. B, Zheng. X, Stiffness and strength development of the soft clay stabilized by the one-part geopolymer under one-dimensional compressive loading[J].Soils and Foundations, 2021:61(4):974-988

[14] Min. Y, Wu. J*, Li. B, The effects of fly ash content on the strength development of soft clay stabilized by one-part geopolymer under curing stress[J].ASCE Journal of Materials in Civil Engineering, 2021:33(10):04021274

[13] Zheng. X, Wu. J*, Early Strength development of soft clay stabilized by one-part ground granulated blast furnace slag and fly ash based geopolymer[J].Frontiers in Materials, 2021:8:616430

[12] Wu. J, Liu. X, Wu. H et al., Dynamic compressive behavior of asphalt concrete material under impact load[J].ASTM Journal of Testing and Evaluation, 2020:48(4):2768-2785

[11] Yan. Q, Liu. C, Wu. J* et al., Experimental and numerical investigation of reinforced concrete pile subjected to near-field non-contact underwater explosion[J].International Journal of Structural Stability and Dynamics, 2020:48(4):2040003

[10] Wang. Z, Wu. H, Fang. Q, Wu. J, Experimental study on the residual axial capacity of ultra-high performance cementitious composite filled steel tube column under contact explosion[J].Thin-Walled Structures, 2020:147:106515

[9] Wang. Z, Wu. H, Fang. Q, Wu. J, Numerical study on the residual axial capacity of ultrahigh performance cementitious composite filled steel tube (UHPCC-FST) column under contact explosion[J].Thin-Walled Structures, 2020:153:106832

[8] Wang. Z, Wu. H, Wu. J, Fang. Q, Experimental study on the residual seismic resistance of ultra-high performance cementitious composite filled steel tube (UHPCC-FST) after contact explosion[J].Thin-Walled Structures, 2020:154:106852

[7] Yu. J, Gan. Y, Wu. J*, Wu. H, Effect of concrete masonry infill walls on progressive collapse performance of reinforced concrete infilled frames[J].Engineering Structures, 2019:191:179-193

[6] Wu. J, Liu. X, Zhou. H, Li. L, Liu. Z, Experimental and numerical study on soft-hard-soft (SHS) cement based composite system under multiple impact loads[J].Materials and Design, 2018:139:234-257

[5] Ali. S, Liu. X, Thambiratnam. D, Gu. Y, Wu. J, Parametric study on cement treated aggregate panel under impact load[J].Archives of Civil and Mechanical Engineering, 2018:18:622-629

[4] Wang. G, Yuan. M, Miao. Y, Wu. J, Wang. Y, Experimental study on seismic response of underground tunnel-soil-surface structure interaction system[J].Tunnelling and Underground Space Technology, 2018:76:145-159

[3] Wu. J, Liu. X, Performance of soft-hard-soft (SHS) cement based composite subjected to blast loading with consideration of interface properties[J].Frontiers of Structural and Civil Engineering, 2015:9(3):323-340

[2] Wu. J, Liu. X, Chew. SH, Parametric study on cement based soft-hard-soft (SHS) multi-layer composite pavement against blast load[J].Construction and Building Materials, 2015:98:602-619

[1] Wu. J, Chew. SH, Field performance and numerical model of multi-layer pavement system for blast load[J].Construction and Building Materials, 2014:52:177-188

中文文章

[13] 郑溢雯, 吴 俊*, 杨爱武, 李 博, 顾 珑, 采用固体硅酸钠激发的一步法地质聚合物在软土固化中的适用性研究[J].岩土力学, 2024:45(7):2072-2084

[12] 蒋新彧, 征西遥, 吴 俊*, 杨爱武, 李 博, HNO3H2SO4侵蚀作用下地质聚物固化软土的抗酸性能研究[J].岩土力学, 2024:

[11] 朱 强, 户 国, 吴 俊*, 聚酯纤维对一步法地质聚合物固化软土增韧性的试验研究[J].工程地质学报, 2024:

[10] 杜 刚, 李 亮, 王子晨, 吴 俊, 杜修力,碳纤维混凝土高温冷却后动态压缩性能试验研究[J].材料导报, 2024:

[9] 周兆鹏, 闫秋实, 田栓柱, 吴 俊, 李建武, 爆炸荷载作用下装配式钢筋混凝土板抗爆性能试验研究[J].天津大学学报(自然科学与工程技术版), 2022:55(6):611-620

[8] 李 亮, 栾贻恒, 吴 俊, 杜修力, 吴文杰, 钢网片-聚乙烯纤维增强水泥基复合材料中低速动态拉伸性能试验研究[J].材料导报, 2022:36(5):1-6

[7] 刘子超, 吴 俊*, 喻 君, 冯晓伟, 爆炸荷载作用下钢筋混凝土构件缩尺效应的数值模拟研究[J].结构工程师, 2022:38(4):16-28

[6] 吴 俊, 征西遥, 杨爱武, 李延波, 矿渣-粉煤灰基地质聚合物固化淤泥质土的抗压强度试验研究[J].岩土力学, 2021:42(3):647-655

[5] 征西遥, 刘秀秀, 吴 俊*, 董 毅, 超细水泥对固化软土早期抗压强度影响的试验研究[J].工程地质学报, 2020:28(4):685-696

[4] 彭 帅, 李 亮, 吴 俊, 姜锡权, 杜修力, 高温条件下钢纤维混凝土动态抗压性能试验研究[J].振动与冲击, 2019:38(22):149-154

[3] 黄振恩,吴 俊*,张 洋,考虑流固耦合效应的盾构隧道开挖面稳定性研究[J]. 现代隧道技术, 2018:50(5):61-71

[2] 吴 俊, 李 亮, 杜修力, 冲击荷载作用下新型多层道面体系动态性能试验[J].天津大学学报(自然科学与工程技术版), 2017:50(12):1321-1328

[1] 吴 俊, 杜修力, 李 亮, 中高应变率下沥青混凝土动力增长系数研究[J].天津大学学报(自然科学与工程技术版), 2017:50(9):921-930


每年拟招收硕士生1~2名,欢迎报考!