Journal Papers in English丨英文期刊论文

  1. Chen, P., Wang, B., Zhang, Z., Li, T., Dai, K. (2023). A generalized model of lead rubber bearing considering large strain stiffening and degradation. Engineering Structures, 275, 115264. (link)

  2. Dai, K., Yang, Y., Li, T., Ge, Q., Wang, J., Wang, B., Chen, P., Huang, Z. (2022). Seismic analysis of a base-isolated reinforced concrete frame using high damping rubber bearings considering hardening characteristics and bidirectional coupling effect. Structures, 46, 698-712. (link)

  3. Ghafoori, E., Wang, B., Andrawes, B. (2022). Shape memory alloys for structural engineering: An editorial overview of research and future potentials. Engineering Structures, 273, 115138. (link)

  4. Li, T., Yang, Y., Xu, J., Dai, K., Ge, Q., Wang, J., Chen, P., Wang, B., Huang, Z. (2022). Hysteretic behavior of high damping rubber bearings under multiaxial excitation. Soil Dynamics and Earthquake Engineering, 163, 107549. (link)

  5. Chen, P., Wang, B., Dai, K., Li, T. (2022). Analytical and numerical investigations of base isolation system with negative stiffness devices. Engineering Structures, 268, 114799. (link)

  6. Chen, ZP., Wang, B. Zhu, S, Wu, G. (2022). Two-level performance-based seismic design approach for steel frames with novel self-centring seismic base isolators. Journal of Constructional Steel Research, 195, 107352. (link)

  7. Chen, ZP., Zhu, S., Yu, H., Wang, B. (2022). Development of novel SMA-based D-type self-centering eccentrically braced frames. Engineering Structures, 260, 114228. (link)

  8. Wang, B., Zhu, S. (2022). Cyclic behavior of iron-based shape memory alloy bars for high-performance seismic devices. Engineering Structures, 252, 113588. (link)

  9. Wang, B. (2021). The innovative structural systems at the heart of China’s surge in super high-rise structures. Proceedings of the Institution of Civil Engineers - Civil Engineering, 174(4), 149-149. (link) (This is a briefing)

  10. Wang, B., Zhu, S., Casciati, F., Chen, K., Jiang, H. (2021). Cyclic behavior and deformation mechanism of superelastic SMA U-shaped dampers under in-plane and out-of-plane loadings. Smart Materials and Structures, 30, 055009. (link)

  11. Gu, Q., Zhang, N., Wang, B., Zhu, S. (2021) Accurate response sensitivity analysis of a thermomechanical constitutive model for superelastic SMAs. Journal of Engineering Mechanics, 147(5), 04021026. (link)

  12. Wang, B., Nishiyama, M., Zhu, S., Tani, M., Jiang, H. (2021). Development of novel self-centering steel coupling beams without beam elongation for earthquake resilience. Engineering Structures, 232, 111827. (link)

  13. Wang, J., Wang, B., Zhang, C., Liu, Z. (2021). Effectiveness and robustness of an asymmetric nonlinear energy sink-inerter for dynamic response mitigation. Earthquake Engineering & Structural Dynamics, 50(6), 1628-1650. (link)

  14. Wang, B., Zhu, S., Chen, K., Huang, J. (2020). Development of superelastic SMA angles as seismic-resistant self-centering devices. Engineering Structures, 218, 110836. (link)

  15. Wang, B., Zhu, S., Casciati, F. (2020). Experimental study of novel self-centering seismic base isolators incorporating superelastic shape memory alloys. Journal of Structural Engineering, 146(7), 04020129. (link)

  16. Wang, J., Wang, B., Liu, Z., Li, H., Zhang, C. (2020). Seismic response mitigation of building structures with a novel vibro-impact dual-mass damper. Engineering Structures, 215, 110673. (link)

  17. Wang, J., Wang, B., Wierschem, N. E., Spencer Jr, B. F. (2020). Dynamic analysis of track nonlinear energy sinks subjected to simple and stochastic excitations. Earthquake Engineering & Structural Dynamics, 49(9), 863-883. (link)

  18. Wang, J., Wang, B., Liu, Z., Zhang, C., Li, H. (2020). Experimental and numerical studies of a novel asymmetric nonlinear mass damper for seismic response mitigation. Structural Control and Health Monitoring, 27(4), e2513. (link)

  19. Wang, J., Wierschem, N. E., Wang, B., Spencer Jr, B. F. (2020). Multi-objective design and performance investigation of a high‐rise building with track nonlinear energy sinks. The Structural Design of Tall and Special Buildings, 29(2), e1692. (link)

  20. Wang, B., Zhu, S., Zhao, J., Jiang, H. (2019). Earthquake resilient RC walls using shape memory alloy bars and replaceable energy dissipating devices. Smart Materials and Structures, 28(6), 065021. (link)

  21. Wang, B., Jiang, H., Wang, J. (2019). Numerical simulation and behavior insights of steel columns with SMA bolts towards earthquake resilience. Journal of Constructional Steel Research, 161, 285-295. (link)

  22. Wang, J., Li, H., Wang, B., Liu, Z., Zhang, C. (2019). Development of a two-phased nonlinear mass damper for displacement mitigation in base-isolated structures. Soil Dynamics and Earthquake Engineering, 123, 435-448. (link)

  23. Yu, J., Ye, J., Zhao, B., Xu, S., Wang, B., Yu, K. (2019). Dynamic response of concrete frames including plain ductile cementitious composites. Journal of Structural Engineering, 145(6), 04019042. (link)

  24. Wang, B., Zhu, S., Qiu, C. X., Jin, H. (2019). High-performance self-centering steel columns with shape memory alloy bolts: Design procedure and experimental evaluation. Engineering Structures, 182, 446-458. (link)

  25. Wang, B., Liang, J., Lu, Z. (2019). Experimental investigation on seismic behavior of square CFT columns with different shear stud layout. Journal of Constructional Steel Research, 153, 130-138. (link)

  26. Wang, B., Zhu, S. (2018). Cyclic tension–compression behavior of superelastic shape memory alloy bars with buckling-restrained devices. Construction and Building Materials, 186, 103-113. (link)

  27. Wang, B., Zhu, S. (2018). Superelastic SMA U-shaped dampers with self-centering functions. Smart materials and structures, 27(5), 055003. (link)

  28. Wang, B., Zhu, S. (2018). Seismic behavior of self-centering reinforced concrete wall enabled by superelastic shape memory alloy bars. Bulletin of Earthquake Engineering, 16(1), 479-502. (link)

  29. Wang, B., Zhu, S., Xu, Y. L., Jiang, H. (2018). Seismic retrofitting of non-seismically designed RC beam-column joints using buckling-restrained haunches: Design and analysis. Journal of Earthquake Engineering, 22(7), 1188-1208. (link)

  30. Wang, B., Jiang, H.*, Lu, X. (2017). Seismic performance of steel plate reinforced concrete shear wall and its application in China Mainland. Journal of Constructional Steel Research, 131, 132-143. (link)

  31. Wang, B., Jiang, H., Lu, X. (2017). Experimental and numerical investigations on seismic behavior of steel truss reinforced concrete core walls. Engineering Structures, 140, 164-176. (link)

  32. Wang, B., Jiang, H. (2017). Experimental study on seismic performance of steel plate reinforced concrete tubes under cyclic loading. The Structural Design of Tall and Special Buildings, 26(16), e1345. (link)

  33. Jiang, H., Wang, B., Lu, X. (2013). Experimental study on damage behavior of reinforced concrete shear walls subjected to cyclic loads. Journal of earthquake engineering, 17(7), 958-971. (link)

  34. Lu, X., Wang, B., Jiang, H., Li, J., Lu, W. (2013). Shaking table tests on a complex high-rise structure with two towers and lapping transfer columns. Journal of Earthquake and Tsunami, 7(04), 1250030. (link)

Journal Papers in Chinese丨中文期刊论文

  1. ​Jiang, H., Wang, B., Lu, X. (2015). Elasto plastic analysis of reinforced concrete shear walls based on cyclic soften membrane model. Journal of Tongji University. 43(5), 676-684. 
    蒋欢军, 王斌, 吕西林. 基于循环软化膜理论的钢筋混凝土剪力墙弹塑性分析,同济大学学报(自然科学版),43(5), 2015:676-684.

  2. Jiang, H., Wang, B., Lu, X., Gu, Q. (2014). Seismic performance of RC composite shear walls with different steel embedded layout. Earthquake Engineering and Engineering Dynamics,34, 478-485.
    蒋欢军, 王斌, 吕西林, 古泉. 不同配钢形式RC组合剪力墙抗震性能分析, 地震工程与工程振动, 34(S1), 2014: 478-485.

  3. Jiang, H., Wang, B.*, Lu, X. (2014). Concepts and measures for improving seismic performance of reinforced concrete shear wall. Journal of Tongji University, 42(2), 1-8. (Top Articles in Outstanding Science and Technology Journals of China)
    蒋欢军, 王斌, 吕西林. 提高钢筋混凝土剪力墙抗震性能的思想与方法, 同济大学学报(自然科学版), 42(2), 2014: 1-8. (此论文入选领跑者5000-中国精品科技期刊顶尖学术论文)

  4. Wang, B., Jiang, H., Lu, X. (2014). Numerical simulation of steel plate-reinforced concrete composite shear wall. Journal of Disaster Prevention and Mitigation Engineering, 2014,34(6),705-711.
    王斌, 蒋欢军, 吕西林. 内置钢板钢筋混凝土组合剪力墙数值模拟, 防灾减灾工程学报, 34(6), 2014: 705-711.

  5. Jiang, H., Wang, B., Lu, X.. (2013). Seismic damage analysis and design suggestions for staircases in RC frame structures. Journal of Vibration and Shock, 32(3), 22-28. (Top Articles in Outstanding Science and Technology Journals of China)
    蒋欢军, 王斌, 吕西林. 钢筋混凝土框架结构楼梯震害分析与设计建议, 振动与冲击, 32(3), 2013: 22-28. (此论文入选领跑者5000-中国精品科技期刊顶尖学术论文)

  6. Jiang, H., Wang, B., Lu, X., Chen Y. (2011). Seismic analysis and shaking table test of China Pavilion for EXPO 2010 Shanghai. Journal of civil, architectural and environmental, 33(3), 13-18.
    蒋欢军, 王斌, 吕西林, 陈云. 上海世博会中国馆抗震分析与振动台模型试验研究, 土木建筑与环境工程, 33(3), 2011: 13-18.

  7. Jiang, H., Wang, B., Lu, X. (2010). Performance limit States and deformation limits of RC beams and columns. Building Structure, 40(1), 10-14.
    蒋欢军, 王斌, 吕西林. 钢筋混凝土梁和柱性能界限状态及其变形限值, 建筑结构, 40(1), 2010: 10-14.

Papers in International Conferences丨国际会议论文

  1. Wang, B., Zhu, S., Casciati, F. (2020). Development of novel self-centering seismic base isolators incorporating SMAs for earthquake resilience. 15th Annual Meeting of Japan Association for Earthquake Engineering (JAEE), Paper No. C-5-3_T2020-011, Dec. 2-3, Japan.

  2. Wang, B., Nishiyama, M., Tani, M., Wang, S., Liu, Y., Nagaya, S. (2020). Development of a novel self-centering steel coupling beam with SMA bolts and energy dissipation devices, 17th World Conference on Earthquake Engineering (17WCEE), Paper No. C002231, Sep. 13-18, Sendai, Japan.

  3. Wang, B., Nishiyama, M., Tani, M. (2020). Development of a novel self-centering coupling beam for RC coupled wall system. FIB Symposium 2020, Nov. 22-24, Shanghai, China.

  4. Wang, B., Zhu, S. (2019). Seismic upgrade of self-centering RC walls using shape memory alloy bars and replaceable energy dissipating devices. The16th East Asia-Pacific Conference on Structural Engineering & Construction (EASEC16), Dec. 3-6, Brisbane, Australia.

  5. Wang, B., Zhu, S. (2018). Experimental investigation of self-centering steel columns with SMA bolts. Ninth International Conference on Advances in Steel Structures (ICASS’2018), Dec. 5-7, Hong Kong, China.

  6. Zhu, S., Wang, B. (2018). Towards earthquake resilience: Using superelastic SMA for high-performance seismic-resistant structures. 2nd International Workshop on Resilience, Oct. 31-Nov. 2, Nanjing and Shanghai, China.

  7. Wang, B., Qiu, C.X., Jin, H., Zhu, S. (2017). Cyclic behavior of self-centering steel columns with SMA bolts. The 15th East Asia-Pacific Conference on Structural Engineering and Construction (EASEC15), Oct. 11-13, Xi’an, China.

  8. Jiang, H., Wang, B., Lu, X. (2015). Experimental study on damage behavior of steel plate-reinforced concrete tubes. 6th International Conference on Advances in Experimental Structural Engineering, 11th International Workshop on Advanced Smart Materials and Smart Structures Technology, Aug. 1-2, Urbana-Champaign, United States.

  9. Wang, B., Jiang, H., Lu, X. (2012). Experimental study on damage behavior of reinforced concrete shear wall with modern detailing. The Twenty-fifth KKCNN Symposium on Civil Engineering, pp. 472-475, Oct. 22-24, Busan, Korea.

  10. Wang, B., Jiang, H., Lu, X. (2012). Seismic performance of steel plate-reinforced concrete composite shear wall. 15th World Conference on Earthquake Engineering (15WCEE), Paper No. 1232, Sep. 24-28, Lisboa, Portugal.

  11. Wang, B., Jiang, H., Lu, X. (2011). Study on the seismic performance of a complex high-rise structure with two towers and lapping transfer columns by shaking table tests. The 4th International Conference on Advances in Experimental Structural Engineering, Jun. 29-30, Ispra, Italy.

  12. Wang, B., Jiang, H., Lu, X. (2011). Seismic analysis of RC structure under multiple earthquakes. The 8th International Conference on Urban Earthquake Engineering, Paper No. 11-086, Mar. 7-8, Tokyo, Japan.

  13. Jiang, H., Wang, B., Lu, X., Yang, J. (2010). Shaking table tests and numerical analysis of structural model China Pavilion for EXPO 2010 Shanghai. The 11th International Symposium on Structural Engineering, pp. 194-200, Dec. 18-20, Guangzhou, China.

Papers in Chinese Conferences丨国内会议论文

  1. Wang, B., Zhang, C., Lu, X., (2013). Nonlinear time history analysis of a steel reinforced concrete frame-concrete tube structure. The 10th Sino-Japanese Structural Engineering Conference, pp. 235-243, Nov. 30-Dec. 1, Nanjing, China.
    王斌, 张翠强, 吕西林. 型钢框架-混凝土核心筒和钢框架-支撑核心筒结构弹塑性时程分析, 第十届中日建筑结构技术交流会, pp. 235-243, 2013年11月30日-12月1日, 南京。

  2. Wang, B., Jiang, H. (2009). Considering modeling stairs on the seismic performance of overall structures. The Symposium of Earthquake Engineering and Mitigate Earthquake in commemoration of the first anniversary of the Wenchuan earthquake, pp. 322-327, May 12-14, Chengdu, China.
    王斌, 蒋欢军. 考虑楼梯整体建模对结构抗震性能的影响, 纪念汶川地震一周年地震工程与减轻地震灾害研讨会, pp. 322-327, 2009年5月12日-14日, 成都。

Technical Reports & Book Chapter研究报告与图书章节   

  1. Wang, B., Zhang, C., Lu, X. (2013). “Nonlinear time history analysis of a steel reinforced concrete frame-concrete tube structure and a steel frame-braced tube structure”. Research Institute of Structural Engineering and Disaster Reduction, Tongji University, 44 pp.
    王斌, 张翠强, 吕西林. 钢框架-混凝土核心筒结构和钢框架支撑结构动力弹塑性分析, 结构工程与防灾研究所, 同济大学, 44页。

  2. Wang, B., Li, J., Zhang, C. (2010). “Shaking table test of Project No. 147 building in Huangpu district, Shanghai”. State Key Laboratory of Disaster Reduction in Civil Engineering, Tongji University, 98 pp.
    王斌, 李检保, 张翠强. 上海黄浦区174街坊项目模拟地震振动台试验研究报告, 土木工程防灾国家重点实验室, 同济大学, 98页。

  3. Yue, J., Wang, B., Qian, J. (2008). “Seismic analysis of China National Pavilion for EXPO 2010 Shanghai”. State Key Laboratory of Disaster Reduction in Civil Engineering, Tongji University, 99 pp.
    岳建广, 王斌, 钱江. 中国2010年上海世博会中国馆国家馆结构抗震性能计算分析报告, 土木工程防灾国家重点实验室, 同济大学, 99页。

  4. Jiang, H., Wang, B. (2011) Seismic damage analysis of reinforced concrete frame structures considering the effect of staircases, in book “Study on seismic damage of Wenchuan earthquake”, Editor: State Key Laboratory of Disaster Reduction in Civil Engineering. Shanghai, Tongji University Press, pp. 119-139.
    蒋欢军, 王斌. 现浇楼梯对钢筋混凝土框架结构抗震性能影响分析, “汶川地震震害研究”第9章, 编者: 土木工程防灾国家重点实验室, 同济大学出版社, 页码: 119-139, 2011年。

Patents专利 

  1. Wang, B., Zhu, S. “Self-centering energy dissipating brace”. China Invention Patent No. CN110206178B, Grant Date: Jun. 16, 2021.
    王斌, 朱松晔. “自复位耗能支撑装置”, 中国发明专利CN110206178B, 授权日期: 2021年6月16日。

  2. Wang, B., Zhu, S. “Self-centering coupling beam enabled by superelastic shape memory alloy”. China Invention Patent No. CN108222369B, Grant Date: Feb. 4, 2021.
    王斌, 朱松晔. “一种基于超弹性形状记忆合金的自复位连梁”, 中国发明专利CN108222369B, 授权日期: 2021年2月4日。

  3. Wang, B., Zhu, S. “Hybrid self-centering and viscous dampers”. China Invention Patent No. CN110173146B, Grant Date: Nov. 27, 2020.
    王斌, 朱松晔. “自复位黏滞复合阻尼器”, 中国发明专利CN110173146B, 授权日期: 2020年11月27日。

  4. Wang, B., Jiang, H. “A novel self-centering steel plate shear wall with superelastic shape memory alloy”, China Invention Patent No. CN106592822B, Grant Date: Oct. 1, 2019.
    王斌, 蒋欢军. “一种基于超弹性形状记忆合金螺杆的自复位钢板剪力墙”, 中国发明专利CN106592822B, 授权日期: 2019年10月1日。