汪俊華,1987年5月生�,博士、校聘教授��,主要從事自復(fù)位鋼筋混凝土工程結(jié)構(gòu)開發(fā)及抗震性能����、工程結(jié)構(gòu)多災(zāi)害耦合效應(yīng)等的教學(xué)與科研工作。2021年入選深圳市高層次人才(后備級)���,2022年為日本學(xué)術(shù)振興會(JSPS)外國人特別研究員項目獲得者�,是2015年度日本國費全額獎學(xué)金獲得者��。
主持國家自然科學(xué)基金項目2項����,日本學(xué)術(shù)振興會(JSPS)外國人特別研究員項目1項,作為骨干參加國家自然科學(xué)基金面上項目3項��、深圳市孔雀團隊項目1項���。發(fā)表論文30余篇��,其中SCI檢索23�,授權(quán)發(fā)明專利3件。
? 主要研究領(lǐng)域:
l 自復(fù)位鋼筋混凝土工程結(jié)構(gòu)開發(fā)及抗震性能評價
l 工程結(jié)構(gòu)多災(zāi)害耦合效應(yīng)
l 新型預(yù)制滾壓路基路面建造技術(shù)及性能評價
? 受教育經(jīng)歷
2005/09-2009/06��,安徽理工大學(xué)��,土木工程專業(yè)���,工學(xué)學(xué)士�����;
2009/09-2012/03,江蘇科技大學(xué)��,結(jié)構(gòu)工程專業(yè)����,工學(xué)碩士。
2013/04-2013/09��,日本神戶大學(xué)���,建筑學(xué)專業(yè)���,研修生����。
2013/10-2016/09�����,日本神戶大學(xué)��,建筑學(xué)專業(yè)�����,工學(xué)博士���。
? 研究工作經(jīng)歷
2016/11 – 2019/12�,必贏3003no1線路檢測中心���,必贏3003no1線路檢測中心�����,博士后�����;
2020/05 – 2022/12�����,深圳大學(xué)���,土木與交通工程學(xué)院����,專職副研究員�;
2022/11 – 2024/11,日本學(xué)術(shù)振興會(JSPS)��,外國人特別研究員�;
2025/03 至今 �,必贏3003no1線路檢測中心,必贏3003no1線路檢測中心�,校聘教授。
? 承擔(dān)的科研項目
項目名稱�、編號 | 項目來源 | 起止年月 | 負責(zé)內(nèi)容 |
低粘結(jié)高強鋼筋混凝土框架結(jié)構(gòu)抗震及自復(fù)位性能研究(52278194) | 國家自然科學(xué)基金 | 2022.01-2026.12 | 主持 |
付著強度の低い超高強度鉄筋を主筋に用いたレジリエントなRC部材のせん斷性狀と評価(22P22357) | 日本學(xué)術(shù)振興會(JSPS) | 2022.09-2024.08 | 主持 |
主筋脫粘鋼筋混凝土柱可恢復(fù)性機理及抗震性能研究(51708288) | 國家自然科學(xué)基金 | 2018.01-2020.12 | 主持 |
地震火災(zāi)后鋼筋混凝土柱的殘余力學(xué)性能研究(51678303) | 國家自然科學(xué)基金 | 2017.01-2020.12 | 骨干 |
大空間建筑火災(zāi)下弦支穹頂結(jié)構(gòu)的力學(xué)行為及抗火設(shè)計理論研究(51878348) | 國家自然科學(xué)基金 | 2019.01-2022.12 | 骨干 |
濱海環(huán)境下新型ECC-FRP螺旋筋鋼筋混凝土組合柱耐久性及抗震性能研(52078299) | 國家自然科學(xué)基金 | 2021.01-2024.12 | 骨干 |
采用低粘結(jié)力高強鋼筋的圓截面抗滑樁結(jié)構(gòu)性能研究(SKLGP2016K005) | 成都理工大學(xué)地質(zhì)災(zāi)害防治與地質(zhì)環(huán)境保護國家重點實驗室開放課題 | 2016.01-2017.12 | 主持 |
? 代表性論文(按發(fā)表時間倒序)
[1] Wang JH*, Sun YP. Axial-shear-flexure interactive behavior and completed shear strength model of reinforced concrete members considering steel-bond slip [J]. Bulletin of Earthquake Engineering, 2025. https://doi.org/10.1007/s10518-025-02115-y
[2] Hang ZY, Mi ZK, Wu YF, Wang JH*, Yu Y*. Fracture performance of concrete-epoxy mortar interface subjected to bending and shear: experimental and numerical study. Journal of Building Engineering, 2024, 97: 110887.
[3] Guan MS, Yao RL, Wang JH*, Wang X, Li Y. Compressive behavior of manufactured sand recycled coarse aggregate concrete-filled steel tubular short columns. Constructional and Building Materials, 2024, 451: 138907.
[4] Wang JH*, Du DF, Su C. Seismic fragility and post-earthquake reparability of concrete encased-and-filled steel tubular bridge columns with debonded high-strength reinforcements. Bulletin of Earthquake Engineering, 2023, 21: 4877-4904.
[5] Guan MS, Sha M, Wang JH*, Huang XR, Jin GZ. Cyclic behavior of self-slitting squat composite shear walls with concrete-filled steel tubes: experiment. Journal of Constructional Steel Research, 2023, 210: 108054
[6] Wang JH*, Sun YP. Shear strength behavior of high-strength fly ash concrete beams with low-bond reinforcement. Structures, 2023, 54: 1756-1771.
[7] Wang JH*, Sun YP. Seismic safety and post-earthquake resilience of frame with debonded high-strength reinforced concrete-encased-and-filled steel tubular columns. Journal of Earthquake Engineering, 2023, 27(13):3632-3657.
[8] Du DF, Wang JH*, Wang X, Su C. Compressive behavior and stress-strain model of square confined ambient-cured fly ash and slag-based geopolymer concrete. Case Studies in Construction Materials, 2022, 17: e01203. https://doi.org/10.1016/j.cscm.2022.e01203
[9] Wang JH*, Sun YP. Seismic behaviors and resilience of concrete-encased concrete-filled steel tubular columns with debonded high-strength rebars: experiment and assessment. Journal of Earthquake Engineering. 2022, 26:15:8142-8168.
[10] Wang JH*, Sun YP. Seismic fragility and post-earthquake reparability of concrete frame with low-bond high-strength reinforced concrete column. Structures, 2022, 37: 185-202.
[11] Wang JH*, Sun YP*, Takeuchi T. Seismic fragility and post-earthquake reparability of circular reinforced concrete bridge columns with low-bond high-strength reinforcements. Structures, 2021, 34: 840-855.
[12] Wang JH*, Zhang X, Kunnath S, He J, Xiao Y. Post-earthquake fire resistance and residual seismic capacity of RC columns. ACI Structural Journal, 2021, 118(4): 123-135.
[13] Wang JH, Cai GC*, Larbi AS. Lateral Behavior of Rectangular Concrete Columns Reinforced by Partially Debonded High-Strength Reinforcements Based on a Proposed Equivalent Stress Block. Bulletin of Earthquake Engineering, 2021, 19: 1901-1930.
[14] Wang JH*, Kunnath S, He J, Xiao Y. Post-earthquake fire resistance of circular concrete-filled steel tubular columns. ASCE Journal of Structural Engineering. 2020, 146(6): 04020105.
[15] Wang JH*. Cyclic behaviors of reinforced concrete beam-column joints debonded reinforcements and beam failure: experiment and analysis. Bulletin of Earthquake Engineering, 2021, 19: 101-133.
[16] Wang JH*, Sun YP*, Takashi T, Koyama T. Seismic behavior of circular fly ash concrete columns reinforced with low-bond high-strength steel rebar. Structures, 2020, 27: 1335-1357.
[17] Wang JH*, Zhao H*, He J. Seismic behaviors and resilient capacity of CFRP-confined concrete columns with partially debonded high-strength steel rebars. Composite Structures. 2019, 222: 110912.
[18] Wang JH*, Cai GC*, Wu Q. Basic mechanical behaviours and deterioration mechanism of RC beams under chloride-sulphate environment. Construction and Building Materials. 2018, 160: 450-461
[19] Wang JH*, He J, Xiao Y. Fire behavior and performance of concrete-filled steel tubular columns: Review and discussion. Journal of Constructional Steel Research, 157(2019):19-31.
[20] Wang JH*, Sun YP. Influence of bond property of longitudinal bars on seismic behaviour of reinforced-concrete columns. Magazine of Concrete Research, 2020, 72(15): 778-798.
[21] Wang JH, Zhao H*. High Performance Damage-Resistant Seismic Resistant Structural Systems for Sustainable and Resilient City: A Review. Shock and Vibration,
[22] Wang JH*, Sun YP. Equivalent stress block to characterise force–displacement behaviour of circular RC column considering steel bond slip. Magazine of Concrete Research. 2020, 72(22): 1171-1188.
[23] Wang X #, Wang JH#, Kazmi SMS#, Wu YF*. Development of new layered compression casting approach for concrete. Cement and Concrete Composites, 2022, 134: 104738. (#:共同第一作者)
? 獲專利情況
[1] 汪俊華,汪勛��,吳宇飛�����。一種壓縮澆筑鋼筋混凝土梁、柱的施工裝置��。ZL 2022 10361057.9��,2022年8月2日�����。
[2] 汪勛�,李迪,黃灝��,汪俊華��,吳宇飛���。一種壓縮澆筑鋼筋混凝土非矩形梁�、柱的施工裝置����。ZL 2022 2 0782327.9,2022年8月23日。
[3] 黃灝����,汪俊華,李迪�,吳宇飛。一種基于單元墻體的密水連接裝置�。ZL 2022 2 1639438.0,2022年10月11日�����。
[4] 李迪��,汪俊華�����,黃灝���,吳宇飛。一種基于墻體的回路型連接裝置��。ZL 2022 2 1642795. 2���,2022年10月11日�。
[5] 李迪,汪俊華�,黃灝,吳宇飛�����。一種基于單元墻體的預(yù)留孔道型連接裝置��。ZL 2022 2 1674151.1, 2022年9月13日�����。
[6] 吳宇飛�����,汪勛���,汪俊華�。一種新型壓縮澆筑混凝土構(gòu)件的模具裝置���。ZL 2022 2 0794019.8����,2022年8月12日。
[7] 杭振園�����,汪俊華���,趙偉���,朱漢華。一種遭受火災(zāi)損傷的混凝土橋梁加固裝置及加固方法�����。ZL201811472442.0�����,2018年12月04日���。
? 主要研究方向
鋼筋混凝土結(jié)構(gòu),鋼-混凝土組合結(jié)構(gòu)�,路基路面。
? 招生專業(yè)
碩士研究生:結(jié)構(gòu)工程,防災(zāi)減災(zāi)及防護工程��。
? 聯(lián)系方式
Email:wangjunhua@njtech.edu.cn