王衛永,1982年生,男,博士,重慶大學土木工程學院教授,博士生導師,2008年6月同濟大學獲得工學博士學位進入重慶大學從事教學和科研工作,現任安全與防災工程研究所所長。2010年3-7月和2011年1-11月分別獲得對方資助赴日本東京理科大學,美國密西根州立大學參加合作研究,2014年5月-2015年10月獲得CSC資助赴美國德州大學奧斯汀分校進行訪問研究。主持國家級和省部級科研項目10餘項,其中國家自然科學基金3項,國家重點研發計畫子課題2項;發表學術論文100餘篇,其中被SCI收錄27篇,EI收錄22餘篇;參加國內外學術會議20次;申請發明專利8項,獲權發明專利1項,實用新型專利3項,軟體著作權3項;獲得教育部科技進步一等獎1項。
基本介紹
- 中文名:王衛永
- 畢業院校:同濟大學
- 學位/學歷:博士
- 職務:重慶大學土木工程學院博士生導師
研究方向,主講課程,學術兼職,學術成果,學術專著,英文期刊論文,科研項目,獲獎記錄,
研究方向
- 鋼結構和組合結構抗火性能;
- 高性能鋼結構體系防災減災設計理論。
主講課程
本科生教學:
專業基礎課《鋼結構設計原理》;
專業課《建築鋼結構設計》;
課程設計《鋼結構課程設計》;
碩士研究生教學:
專業選修課《鋼結構及鋼-混凝土結構抗火設計》
博士研究生教學:
專業課《高等鋼結構2》
專業基礎課《鋼結構設計原理》;
專業課《建築鋼結構設計》;
課程設計《鋼結構課程設計》;
碩士研究生教學:
專業選修課《鋼結構及鋼-混凝土結構抗火設計》
博士研究生教學:
專業課《高等鋼結構2》
學術兼職
中國建築學會抗震防災分會結構抗火專業委員會委員;
中國鋼結構協會房屋建築鋼結構分會理事;
中國鋼結構協會房屋建築鋼結構分會鋼結構教學委員會委員;
中國鋼結構協會結構穩定與疲勞分會理事;
中國消防協會建築防火專業委員會委員;
中國建築學會建築防火綜合技術分會結構與建材專業委員會委員;
中國土木工程學會防火技術分會理事;
教育部學位中心學位論文評審專家;
《土木建築與環境工程》學報編委;
中國建築學會高層建築人居環境委員會常務理事;
《建築鋼結構進展》副主編。
中國鋼結構協會房屋建築鋼結構分會理事;
中國鋼結構協會房屋建築鋼結構分會鋼結構教學委員會委員;
中國鋼結構協會結構穩定與疲勞分會理事;
中國消防協會建築防火專業委員會委員;
中國建築學會建築防火綜合技術分會結構與建材專業委員會委員;
中國土木工程學會防火技術分會理事;
教育部學位中心學位論文評審專家;
《土木建築與環境工程》學報編委;
中國建築學會高層建築人居環境委員會常務理事;
《建築鋼結構進展》副主編。
學術成果
學術專著
[1] 王衛永,李國強.高強度Q460鋼結構抗火設計原理,38萬字,科學出版社,2016.
[2] Weiyong Wang,Venkatesh Kodur. Material properties of steel in fire conditions, Elsevier, 2019.
[2] Weiyong Wang,Venkatesh Kodur. Material properties of steel in fire conditions, Elsevier, 2019.
英文期刊論文
[1]Wang W.Y., Zhou H.Y., Xu L. Creep buckling of high strength Q460 steel columns at elevated temperatures. Journal of Constructional Steel Research,2019,157:414-425.(SCI,EI收錄)
[2].Huanting Zhou, Weiyong Wang, Kang Wang, Lei Xu. Mechanical properties deterioration of high strength steels after high temperature exposure. Constructions and Building Materials, 2019,199:664-675. (SCI,EI收錄)
[3].Zhou Xuhong, Shi Yu, Xu Lei, Xiaomei Yao, Wang Weiyong. A simplified method to evaluate the flexural capacity of lightweight cold-formed steel floor system with oriented strand board subfloor. Thin-walled structures, 2019,134:40-51. (SCI,EI收錄)
[4].Weiyong Wang, Yue Xia,Guoqiang Li. Fire resistance studies on high strength steel structures, International journal of high-rise buildings,2018,7(4):287-298.
[5].Wang Weiyong, Zhang Linbo, Ge Yong. Behaviour of restrained high strength steel columns at elevated temperature. Journal of Constructional Steel Research 2018,148: 251–264.(SCI,EI收錄)
[6].Wang Weiyong, Zhang Linbo, He Pingzhao. A Numerical Investigation on Restrained High Strength Q460 Steel Beams Including Creep Effect. International Journal of Steel Structures,2018,18(5):1497-1507.(SCI,EI收錄)
[7]. Wang Weiyong, Zhou Hongyang, Zhou Yichao,Lei Xu. An approach for predicting fire resistance of high strength Q460 steel beams considering un-uniform temperature distribution. Fire technology, 2018,54(2):437-460. (SCI,EI收錄)
[8]. Wang Weiyong, Wang Kang,Kodur VK, Wang Bin. Mechanical properties of high strength Q690 steel at elevated temperature. Journal of Materials in Civil Engineering, 2018, 30(5):04018062.(SCI,EI收錄)
[9].Wang W.Y., Qin S.Q., Kodur V.K.R. Wang Yuhang. Experimental study on residual stress in welded box-sections after high temperature exposure. Advanced steel construction, 2018,14(1):73-89.(SCI,EI收錄)
[10].Wang W.Y.,Yan S.H. Liu J.P. Test on temperature induced creep in high strength Q460 steel. Materials & Structures,2017,(2): 50-68. (SCI,EI收錄)
[11].Wang W.Y., Wang K., Engelhardt M.D.,Li G.Q. Behavior of steel-concrete partially composite beams subjected to fire—Part 2:Analytical study. Fire Technology,DOI: 10.1007/s10694-016-0624-0. (SCI,EI收錄)
[12].Wang W.Y., Engelhardt M.D., Li G.Q., Huang G.S. Behavior of steel-concrete partially composite beams subjected to fire—Part 1:Experimental study. Fire Technology,2016,1-20.(SCI,EI收錄)
[13].Wang W.Y., Liu T.Z. Experimental and numerical study on post-fire behavior of high-strength Q460 steel columns. Advanced in Structural Engineering, 2016,19(12):1-16. (SCI,EI收錄)
[14].Wang W.Y., Qin S.Q. Experimental investigation of residual stresses in thin-walled welded H-sections after fire exposure. Thin-walled Structures, 2016, (101):109-119. (SCI,EI收錄)
[15].Wang, W., Yan, S., and Kodur, V. Temperature Induced Creep in Low-Alloy Structural Q345 Steel. J. Mater. Civ. Eng., 2016, 28(6): 06016003.(SCI,EI收錄)
[16].Wang W.Y.,Liu T.Z. Liu J.P. Experimental study on post fire mechanical properties of high strength Q460 steel. Journal of Constructional Steel Research, 2015,114:100-109.(SCI,EI收錄)
[17].Wang W.Y., Li G.Q., Ge Y. Residual stress study on welded section of high strength Q460 steel after fire exposure. Advanced steel constructions,2015,11(2):150-164.(SCI,EI收錄)
[18].Wang W.Y., Kodur VK, Yang X.C., Li G.Q. Experimental study on local buckling of axially compressed steel stub columns at elevated temperatures; Thin-walled structures, 2014,82:33-45.(SCI,EI收錄)
[19].Wang W.Y.,Li G.Q. An approach for evaluating fire resistance of high strength Q460 steel columns. Frontier of Structural and Civil Engineering, 2014, 8(1):26-35.
[20].Wang W.Y., Ohmiya Y., Ma G.F. Fire resistance study of axially loaded high strength steel columns. Procedia Engineering,2013,62:690-701.(ISTP收錄)
[21].Wang W.Y., Bing LIU, Kodur V.K. Effect of temperature on strength and elastic modulus of high strength steel. Journal of Materials in Civil Engineering, 2013,25(2):174-182.(SCI,EI收錄)
[22].Wang W.Y., Li G.Q., Kodur V.K. An Approach for Modeling Fire Insulation Damage in Steel Columns, Journal of Structural Engineering, 2013,139(4):491-503.(SCI,EI收錄)
[23].Li G.Q., Wang W.Y. A simplified approach for fire-resistance design of steel-concrete composite beams, Steel & Composite Structures,2013,14(3):295-312.(SCI,EI收錄)
[24].Wang W.Y., Li G.Q. Fire-resistance study of steel columns with partial fire protection damage. Fire Safety Journal, 2009, 44(8):1088-1094.(SCI,EI收錄)
[25].Wang W.Y., Li G.Q. Behavior of steel columns in a fire with partial damage to fire protection. Journal of Constructional Steel Research, 2009, 65(6): 1392-1400.(SCI,EI收錄)
[26].Li G.Q., Wang W.Y., Chen S.W. A simple approach for modeling fireresistance of steel columns with locally damaged fire retardant coating. Engineering Structures, 2009,31(3):617-622.(SCI,EI收錄)
[27].Wang W.Y., Li G.Q., Dong Y.L. A practical approach for fire-resistance design of extended end-plate joints. Journal of Constructional Steel Research, 2008, 64(12):1456-1462.(SCI, EI收錄)
[28].Wang W.Y., Li G.Q., Dong Y.L. Experimental study and spring-component modeling of extended end-plate joints in fire. Journal of Constructional Steel Research, 2007, 63 (8):1127-1137.(SCI, EI收錄)
[2].Huanting Zhou, Weiyong Wang, Kang Wang, Lei Xu. Mechanical properties deterioration of high strength steels after high temperature exposure. Constructions and Building Materials, 2019,199:664-675. (SCI,EI收錄)
[3].Zhou Xuhong, Shi Yu, Xu Lei, Xiaomei Yao, Wang Weiyong. A simplified method to evaluate the flexural capacity of lightweight cold-formed steel floor system with oriented strand board subfloor. Thin-walled structures, 2019,134:40-51. (SCI,EI收錄)
[4].Weiyong Wang, Yue Xia,Guoqiang Li. Fire resistance studies on high strength steel structures, International journal of high-rise buildings,2018,7(4):287-298.
[5].Wang Weiyong, Zhang Linbo, Ge Yong. Behaviour of restrained high strength steel columns at elevated temperature. Journal of Constructional Steel Research 2018,148: 251–264.(SCI,EI收錄)
[6].Wang Weiyong, Zhang Linbo, He Pingzhao. A Numerical Investigation on Restrained High Strength Q460 Steel Beams Including Creep Effect. International Journal of Steel Structures,2018,18(5):1497-1507.(SCI,EI收錄)
[7]. Wang Weiyong, Zhou Hongyang, Zhou Yichao,Lei Xu. An approach for predicting fire resistance of high strength Q460 steel beams considering un-uniform temperature distribution. Fire technology, 2018,54(2):437-460. (SCI,EI收錄)
[8]. Wang Weiyong, Wang Kang,Kodur VK, Wang Bin. Mechanical properties of high strength Q690 steel at elevated temperature. Journal of Materials in Civil Engineering, 2018, 30(5):04018062.(SCI,EI收錄)
[9].Wang W.Y., Qin S.Q., Kodur V.K.R. Wang Yuhang. Experimental study on residual stress in welded box-sections after high temperature exposure. Advanced steel construction, 2018,14(1):73-89.(SCI,EI收錄)
[10].Wang W.Y.,Yan S.H. Liu J.P. Test on temperature induced creep in high strength Q460 steel. Materials & Structures,2017,(2): 50-68. (SCI,EI收錄)
[11].Wang W.Y., Wang K., Engelhardt M.D.,Li G.Q. Behavior of steel-concrete partially composite beams subjected to fire—Part 2:Analytical study. Fire Technology,DOI: 10.1007/s10694-016-0624-0. (SCI,EI收錄)
[12].Wang W.Y., Engelhardt M.D., Li G.Q., Huang G.S. Behavior of steel-concrete partially composite beams subjected to fire—Part 1:Experimental study. Fire Technology,2016,1-20.(SCI,EI收錄)
[13].Wang W.Y., Liu T.Z. Experimental and numerical study on post-fire behavior of high-strength Q460 steel columns. Advanced in Structural Engineering, 2016,19(12):1-16. (SCI,EI收錄)
[14].Wang W.Y., Qin S.Q. Experimental investigation of residual stresses in thin-walled welded H-sections after fire exposure. Thin-walled Structures, 2016, (101):109-119. (SCI,EI收錄)
[15].Wang, W., Yan, S., and Kodur, V. Temperature Induced Creep in Low-Alloy Structural Q345 Steel. J. Mater. Civ. Eng., 2016, 28(6): 06016003.(SCI,EI收錄)
[16].Wang W.Y.,Liu T.Z. Liu J.P. Experimental study on post fire mechanical properties of high strength Q460 steel. Journal of Constructional Steel Research, 2015,114:100-109.(SCI,EI收錄)
[17].Wang W.Y., Li G.Q., Ge Y. Residual stress study on welded section of high strength Q460 steel after fire exposure. Advanced steel constructions,2015,11(2):150-164.(SCI,EI收錄)
[18].Wang W.Y., Kodur VK, Yang X.C., Li G.Q. Experimental study on local buckling of axially compressed steel stub columns at elevated temperatures; Thin-walled structures, 2014,82:33-45.(SCI,EI收錄)
[19].Wang W.Y.,Li G.Q. An approach for evaluating fire resistance of high strength Q460 steel columns. Frontier of Structural and Civil Engineering, 2014, 8(1):26-35.
[20].Wang W.Y., Ohmiya Y., Ma G.F. Fire resistance study of axially loaded high strength steel columns. Procedia Engineering,2013,62:690-701.(ISTP收錄)
[21].Wang W.Y., Bing LIU, Kodur V.K. Effect of temperature on strength and elastic modulus of high strength steel. Journal of Materials in Civil Engineering, 2013,25(2):174-182.(SCI,EI收錄)
[22].Wang W.Y., Li G.Q., Kodur V.K. An Approach for Modeling Fire Insulation Damage in Steel Columns, Journal of Structural Engineering, 2013,139(4):491-503.(SCI,EI收錄)
[23].Li G.Q., Wang W.Y. A simplified approach for fire-resistance design of steel-concrete composite beams, Steel & Composite Structures,2013,14(3):295-312.(SCI,EI收錄)
[24].Wang W.Y., Li G.Q. Fire-resistance study of steel columns with partial fire protection damage. Fire Safety Journal, 2009, 44(8):1088-1094.(SCI,EI收錄)
[25].Wang W.Y., Li G.Q. Behavior of steel columns in a fire with partial damage to fire protection. Journal of Constructional Steel Research, 2009, 65(6): 1392-1400.(SCI,EI收錄)
[26].Li G.Q., Wang W.Y., Chen S.W. A simple approach for modeling fireresistance of steel columns with locally damaged fire retardant coating. Engineering Structures, 2009,31(3):617-622.(SCI,EI收錄)
[27].Wang W.Y., Li G.Q., Dong Y.L. A practical approach for fire-resistance design of extended end-plate joints. Journal of Constructional Steel Research, 2008, 64(12):1456-1462.(SCI, EI收錄)
[28].Wang W.Y., Li G.Q., Dong Y.L. Experimental study and spring-component modeling of extended end-plate joints in fire. Journal of Constructional Steel Research, 2007, 63 (8):1127-1137.(SCI, EI收錄)
科研項目
[1] 名稱:冷彎型鋼夾支薄板剪力牆耐火性能,任務來源:國家自然科學基金,編號:51878096,經費:60萬,起止年月:2019.1-2022.12;
[2] 名稱: 考慮高溫蠕變特性和殘餘應力的高強度鋼柱抗火性能研究,任務來源:國家自然科學基金,編號:51608520,經費:56萬,起止年月:2017.1-2020.12;
[3] 名稱: 鋼結構體系的防災減災設計理論及工程套用,任務來源:科技部國家重點研發計畫,編號:2016YFC0701203,經費:75.0萬,起止年月:2016.7-2020.6;
[2] 名稱: 考慮高溫蠕變特性和殘餘應力的高強度鋼柱抗火性能研究,任務來源:國家自然科學基金,編號:51608520,經費:56萬,起止年月:2017.1-2020.12;
[3] 名稱: 鋼結構體系的防災減災設計理論及工程套用,任務來源:科技部國家重點研發計畫,編號:2016YFC0701203,經費:75.0萬,起止年月:2016.7-2020.6;
獲獎記錄
[1] 2010年獲“上海市研究生優秀成果(博士學位論文)”
[2] 2012年獲“重慶大學十佳優秀青年教師”;
[3] 2014年獲“黃尚廉院士青年創新獎”;
[4] 2018年獲“重慶大學先進工作者”;
[5] 2018年獲“重慶大學唐立新優秀科研教師獎”;
[6] 2018年獲教育部高等學校科技進步一等獎(7/19)。
[2] 2012年獲“重慶大學十佳優秀青年教師”;
[3] 2014年獲“黃尚廉院士青年創新獎”;
[4] 2018年獲“重慶大學先進工作者”;
[5] 2018年獲“重慶大學唐立新優秀科研教師獎”;
[6] 2018年獲教育部高等學校科技進步一等獎(7/19)。