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池寅

发布时间:2018-11-08 19:44  作者:  访问次数:

Chi Yin, Ph.D, Associate Professor, Department of Construction Engineering

Email: yin.chi@whu.edu.cn Tel: 18986292881

Research Gate: https://www.researchgate.net/profile/Yin-Chi-2

个人简介:池寅,19848月,九三学社社员,武汉大学副教授/博士生导师,入选2021首批湖北省青年拔尖人才计划,欧盟地平线计划H2020 “玛丽·居里”学者,2017武汉大学“351人才计划”珞珈青年学者。2012年毕业于英国诺丁汉大学(The University of Nottingham),获博士学位。2013年赴香港科技大学从事博士后研究工作。2018年赴英国兰卡斯特大学(Lancaster University)担任高级研究员。任亚洲混凝土联合会ACF 超高性能混凝土分委会委员、欧洲FIB纤维混凝土结构模拟委员会委员等学术组织委员。先后主持国家自然科学基金、国家重点研发计划专项子课题、欧盟MSCF项目、湖北省人才项目等6项,作为项目骨干参与国家自然科学基金重点项目。主要从事纤维混凝土损伤与破坏研究工作,在Compos StructCem Concr CompCompos Part BEng Struct等期刊发表论文47篇。获国家发明专利7项、软件著作权2项。参编亚洲混凝土联合会ACF规范1部,参编教材2部。担任40余国内外权威期刊审稿人。成果应用于武汉中心等工程。获2017湖北省科技进步一等奖1(11/15),获2021首届全国高校教师教学创新大赛三等奖以及首届湖北省高校教师教学创新大赛一等奖(团队成员)

主讲课程:混凝土结构基本原理(入选2021年度湖北省线上线下混合式一流课程)、混凝土结构与砌体结构设计(国家精品资源共享课程)

研究方向:纤维混凝土本构关系及结构非线性分析、绿色超高性能混凝土微结构调控及多尺度模拟、FRP复材高效利用及结构组合方法、装配式混凝土结构基础理论及应用

 

研究课题:

1. 国家自然科学基金(面上): 钢-聚丙烯混杂纤维混凝土细观疲劳损伤机理及本构关系研究,(编号:51878519),2019-2022(主持);

2. 欧盟H2020玛丽居里基金基于生物材料的环境友好型智能高性能水泥基复合材料设计及应用,(编号:B-SMART 799658),2018-2020 (中方负责人);

3. 国家自然科学基金(青年)钢-聚丙烯混杂纤维混凝土弹塑性损伤本构关系研究,(编号:51608397),2017-2019 (主持);

4. 国家自然科学基金(重点)复杂作用下钢管超高性能混凝土力学性能及设计计算理论研究, (编号:51738011), 2018-2022 (项目骨干) ;

5. 国家重点研发计划专项:高性能纤维增强复合材料与新型结构关键技术研究与应用,(项目编号:2017YFC0703001)——纤维增强复合材料性能提升与建筑高效利用的结构设计理论及方法研究(课题编号:2017YFC0703001-04); 2017-2020 (子课题技术负责人);

6. 国家自然科学基金(面上):钢-聚丙烯混杂纤维混凝土多尺度本构关系:从纳米尺度到宏观尺度,(编号:51478367),2015-2018 (项目骨干);

7. 国家自然科学基金(面上):反复荷载下钢-聚丙烯混杂纤维混凝土粘结性能与节点抗震性能研究,(编号:51278388),2013-2016 (项目骨干);

8. 国家自然科学基金(面上):钢-聚丙烯混杂纤维混凝土本构关系研究, (编号:51078295),2011-2013 (项目骨干);

9. 国家自然科学基金(中德交流项目)超高性能纤维增强水泥基复合材料和构件多尺度优化及增材制造实现,(编号:M-0172),2021-2023(项目骨干);

10. 湖北省自然科学基金(面上)重复荷载下钢-聚丙烯混杂纤维混凝土疲劳损伤演化机理及寿命预测方法,(编号:2020CFB639),2020-2022;(主持);


     近三年SCI论文:

 [1] Li L, Xu L, Huang L, Xu F, Huang Y, Cui K, Zeng Y, Chi Y. Compressive fatigue behaviors of ultra-high performance concrete containing coarse aggregate. Cement and Concrete Composites 2022;128:104425.

[2] Chi Y, Huang B, Saafi M, Fullwood N, Lambert C, Whale E, Hepworth D, Ye J. 2D bio-based nanomaterial as a green route to amplify the formation of hydrate phases of cement composites: Atomistic simulations and analytical characterization. CONSTR BUILD MATER 2021;299:123867.

[3] Huang L, Ye H, Xu L, Chi Y. A mechanistic model for the nonlinear bond behavior of steel reinforcement in concrete. ENG STRUCT 2021;231:111715.

[4] Cai H, Xu L, Chi Y, Yan Y, Yu C, He C. Seismic performance of rectangular ultra-high performance concrete filled steel tube (UHPCFST) columns. COMPOS STRUCT 2021;259:113242.

[5] Lu Q, Xu L, Chi Y, Deng F, Yu M, Hu X. A novel analysis-oriented theoretical model for steel tube confined ultra-high performance concrete. COMPOS STRUCT 2021:113713.

[6] Wang S, Xu L, Yin C, Chen Z, Chi Y. Experimental investigation on the damage behavior of ultra-high performance concrete subjected to cyclic compression. COMPOS STRUCT 2021:113855.

[7] Meng K, Xu L, Chi Y. Experimental investigation on the mechanical behavior of hybrid steel-polypropylene fiber reinforced concrete under conventional triaxial cyclic compression. CONSTR BUILD MATER 2021;291:123262.

[8] Deng F, Chi Y, Xu L, Huang L, Hu X. Constitutive behavior of hybrid fiber reinforced concrete subject to uniaxial cyclic tension: Experimental study and analytical modeling. CONSTR BUILD MATER 2021;295:123650.

[9] Cui K, Xu L, Li X, Hu X, Huang L, Deng F, Chi Y. Fatigue life analysis of polypropylene fiber reinforced concrete under axial constant-amplitude cyclic compression. J CLEAN PROD 2021;319:128610.

[10] Bao H, Yu M, Chi Y, Liu Y, Ye J. Performance evaluation of steel-polypropylene hybrid fiber reinforced concrete under supercritical carbonation. Journal of Building Engineering 2021;43.

[11] Wu F, Xu L, Chi Y, Zeng Y, Deng F, Chen Q. Compressive and flexural properties of ultra-high performance fiber-reinforced cementitious composite: The effect of coarse aggregate. COMPOS STRUCT 2020;236:111810.

[12] Yu M, Yang B, Chi Y, Xie J, Ye J. Experimental study and DEM modelling of bolted composite lap joints subjected to tension. Composites Part B: Engineering 2020;190:107951.

[13] Deng F, Xu L, Chi Y, Wu F, Chen Q. Effect of steel-polypropylene hybrid fiber and coarse aggregate inclusion on the stress–strain behavior of ultra-high performance concrete under uniaxial compression. COMPOS STRUCT 2020;252:112685.

[14] Chi Y, Huang B, Saafi M, Ye J, Lambert C. Carrot-based covalently bonded saccharides as a new 2D material for healing defective calcium-silicate-hydrate in cement: Integrating atomistic computational simulation with experimental studies. Composites Part B: Engineering 2020;199:108235.

[15] Huang L, Chi Y, Xu L, Deng F. A thermodynamics-based damage-plasticity model for bond stress-slip relationship of steel reinforcement embedded in fiber reinforced concrete. ENG STRUCT 2019;180:762.

[16] Hasan H, Huang B, Saafi M, Sun J, Chi Y, Whale E, Hepworth D, Ye J. Novel engineered high performance sugar beetroot 2D nanoplatelet-cementitious composites. CONSTR BUILD MATER 2019;202:546.

[17] Xu L, Wu F, Chi Y, Cheng P, Zeng Y, Chen Q. Effects of coarse aggregate and steel fibre contents on mechanical properties of high performance concrete. CONSTR BUILD MATER 2019;206:97.

[18] Xu L, Lu Q, Chi Y, Yang Y, Yu M, Yan Y. Axial compressive performance of UHPC filled steel tube stub columns containing steel-polypropylene hybrid fiber. CONSTR BUILD MATER 2019;204:754.

[19] Huang L, Ye H, Chu S, Xu L, Chi Y. Stochastic damage model for bond stress-slip relationship of reinforcing bar embedded in concrete. ENG STRUCT 2019:11.

[20] Huang L, Xu L, Chi Y, Deng F, Zhang A. Bond strength of deformed bar embedded in steel-polypropylene hybrid fiber reinforced concrete. CONSTR BUILD MATER 2019:17

 

    专利及软著: 

[1]池寅,徐礼华,孟宽,黄乐,余敏. 基于MATLAB的钢-聚丙烯混杂纤维混凝土屈服面绘图与强度计算软件V1.0, 软件著作权,登记号:2022SR0316077.登记日期:2021-12-01.

[2]余敏, 池寅, 胡煊, 徐礼华, 叶建乔. 混凝土细观骨料模型快速生成系统[简称:FAG system]V1.0, 软件著作权登记号: 2018SR238185, 登记日期: 2018-05-28.

[3]徐礼华,李彪,池寅,李长宁,黄彪,颜燕祥,时豫川. 一种考虑纤维滑移的钢纤维混凝土弹塑性本构模型构建方法。发明专利,专利号:ZL201710404149.X,授权日期:2021-08-03.

[4]姜清辉,池寅,孟晓宇,张云天,刘乳燕. 高抗拉透水混凝土三明治结构及制备方法。发明专利,专利号:ZL201810756179.1, 授权如期:2020-07-10

[5]徐礼华,邓方茜,池寅,余敏,黄乐. 一种可施加测压力的单丝拉拔试验装置。发明专利, 专利号: ZL201710297710.9,授权日期:2019-12-24.

[6]池寅,黄乐,徐礼华,余敏,李彪. ABAQUS中钢-聚丙烯混杂纤维混凝土塑性本构参数的取值方法。发明专利,专利号:ZL201610728736.X, 授权日期:2019-09-17.

[7]余敏, 叶建乔, 鲍浩, 池寅, 徐礼华. 快速生成卵石碎石夹杂的混凝土三维随机骨料模型的方法. 发明专利, 专利号: ZL201710086212.X, 授权日期: 2019-6-5.

[8]余敏, 池寅, 鲍浩, 叶建乔, 徐礼华, 黄俊杰. 快速生成卵石碎石夹杂的混凝土二维随机骨料模型的方法. 发明专利, 专利号: ZL201710086411.0, 授权日期: 2019-5-17.


   奖励与荣誉:

1.首批湖北省青年拔尖人才计划,2021;

2.首届全国高校教师教学创新大赛三等奖,2021;

3.2021年度优秀烛光导航师,2021;

4.湖北省首届高校教师教学创新大赛一等奖,2020;

5.英国混凝土协会Adam-Neville Prize(2/4)2020

6.土木工程专业核心课程湖北省教学团队(7/13),核心成员,2019;

7.欧盟地平线计划H2020Marie-Curie Fellow”,2018;

8.武汉大学“青年拔尖人才”出国研修计划,2018

9.湖北省科技进步一等奖(11/15)2017

10.武汉大学“351计划”珞珈青年学者,2017


 

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