北京交通大学-土木建筑工程学院

基本情况

姓名：	向宏军
职务：	环境学院党委书记
职称：	教授
学历：	研究生
学位：	博士
通信地址：	北京交通大学土木工程楼207
邮编：	100044
办公电话：	010-51684948
电子邮箱：	hjxiang@bjtu.edu.cn

北京交通大学教授、博士生导师，环境学院党委书记，土建学院智能材料与结构研究所所长、智慧建筑及数字建造中心副主任，北京交大建筑勘察设计院执行董事。曾获国家“优青”、教育部“新世纪优秀人才”和北京市“青年英才”等人才项目和计划支持，以及教育部优秀科研成果自然科学二等奖、北京市青年教学名师、宝钢优秀教师、北京交通大学教学教风标兵等荣誉。已培养硕士和博士毕业生30余人，最新信息关注智能材料与结构研究所微信公众号：SMS_Lab 。

主要从事智能材料与结构的研究，包括两个主要研究方向： (1) 车致振动隔振减振，采用人工周期结构或超结构将列车运行产生的振动进行隔离或削弱，进而保护振动敏感建筑。 (2) 车致振动能量收集，将列车运行中产生的结构振动能转化为电能并存储起来，给无线传感网络供电，实现无需外界电源的自供能监测。

主要教育经历：

2004.9-2007.7 北京交通大学，结构工程，博士生（提前攻博）。

2002.9-2004.7 北京交通大学，结构工程，硕士生。

1998.9-2002.7 北方交通大学，土木工程，本科生。

工作经历

2024.1至今北京交通大学，环境学院党委书记

2019.7-2024.5 北京交通大学，土建学院副院长

2014.10至今北京交通大学，教授（破格），博导

2010.11- 2014.09 北京交通大学，副教授

2010.10-2011.9 美国休斯顿大学，访问学者

2007.7 - 2010.10 北京交通大学，讲师

2006.3-2006.8 香港城市大学，研究助理

研究方向

建筑结构
土木工程
交通基础设施
土木水利

招生专业

土木工程博士
土木工程硕士
交通运输博士
土木水利博士

科研项目

主要研究智能材料与结构、工程隔震减振、车致振动能量收集与应用，主持项目为：

国家级项目4项，
省部级项目4项，
其它项目6项。

教学工作

自2007年开始从事教学工作，是北京市青年教学名师、宝钢优秀教师、北京交大课堂教学教风标兵，曾获全国结构力学讲课竞赛一等奖，北京市教学成果一等奖1项，北京交通大学教学成果一等奖2项、二等奖2项。先后讲授《非线性有限元分析》、《弹塑性力学》、《土木工程导论》等课程，并持续主讲以下课程：

《结构力学》，本科，国家一流课程
《结构动力学》，研究生，专业核心课程

参与编写教学辅导书《结构力学精讲及真题详解》，发表教改论文4篇，主持教改项目3项。

论文/期刊

发表论文近70篇，其中SCI检索50余篇，详见 Google scholar ，Web of Science，或者ORCID。主要论文如下：

Wang J Y, Xiang H J, Jing H, Zhu Y J, Zhang Z W. Stochastic analysis for vortex-induced vibration piezoelectric energy harvesting in incoming wind turbulence[J]. Applied Energy, 2025, 377: 124618.
Jing H, Xiang H J, Wang J Y. Modified vortex-induced vibration piezoelectric energy harvester for capturing wind energy from trains moving in tunnels[J]. Sensors and Actuators A: Physical, 2025, 382: 116136.
Yang Y, Xiang H J. A New Analysis Framework for Solving Multiple Frequencies and Solutions of Nonlinear Piezoelectric Energy Harvesters[J]. Communications in Nonlinear Science and Numerical Simulation, 2025, 140: 108433.
Sheng W Q, Xiang H J. A piezoelectric tuned mass damper for simultaneous vibration control and energy harvesting[J]. Smart Materials and Structures, 2024, 33(1): 015019.
Sheng W, Xiang H, Gao L, Wang J, Liang J, Zhang Z. Whole-process analysis and implementation of a self-powered wireless health monitoring system for railway bridges: Theory, simulation and experiment[J]. Engineering Structures, 2024, 316: 118584.
Liu P P, Xiang H J. A space-adiabatic theorem for longitudinal and transversal wave motion analysis of graded metamaterials[J]. Journal of Intelligent Material Systems and Structures, 2024, 35(19): 1511-1526.
Wang J Y, Xiang H J, Ci Y M, Xue X X. Exploring the effect of incoming wind turbulent flow on galloping-based piezoelectric energy harvesting[J]. Mechanical Systems and Signal Processing, 2024, 221: 111714.
Zhang Y R, Xiang H J. A unified theoretical framework of piezoelectric energy harvesters: Euler–Bernoulli, Timoshenko and Reddy beam models with the high-order electric field assumption[J]. Acta Mechanica, 2024, 235: 5643-5660.
Zhang Y R, Xiang H J, Deng H S, Zhang X B, Zhan J W, Shi Z F. System-level modeling and design method of an array of piezoelectric energy harvesters under typical ambient vibration[J]. Journal of Intelligent Material Systems and Structures, 2023, 34(3): 261-278.
Zhang Z W, Xiang H J, Tang L H, Yang W Q. A comprehensive analysis of piezoelectric energy harvesting from bridge vibrations[J]. Journal of Physics D-Applied Physics, 2023, 56(1): 014001.
Yang Y, Xiang H J. A simple and precise formula for magnetic forces in nonlinear piezoelectric energy harvesting[J]. Nonlinear Dynamics, 2023, 111(7): 6085-6110.
Wang J Y, Xiang H J. Stochastic analysis of galloping piezoelectric energy harvesters under turbulent flow conditions based on the probability density evolution method[J]. Mechanical Systems and Signal Processing, 2023, 200: 110638.
Yi Z C, Zhang Z W, Huang J K, Xiang H J, He C O, Liu L H. Mechanism analysis and experimental verification of the bulging vibration characteristic of a fluid-solid metamaterial[J]. Engineering Structures, 2023, 279: 115602.
Sheng W Q, Xiang H J, Zhang Z W, Yuan X P. High-efficiency piezoelectric energy harvester for vehicle-induced bridge vibrations: Theory and experiment[J]. Composite Structures, 2022, 299: 116040.
Cao Y, Zong R, Wang J, Xiang H, Tang L. Design and performance evaluation of piezoelectric tube stack energy harvesters in railway systems[J]. Journal of Intelligent Material Systems and Structures, 2022, 33(18): 2305-2320.
Wang J J, Cao Y L, Xiang H J, Zhang Z W, Liang J R, Li X, Ding D Y, Li T, Tang L H. A piezoelectric smart backing ring for high-performance power generation subject to train induced steel-spring fulcrum forces[J]. Energy Conversion and Management, 2022, 257: 115442.
Zhan J, Wang Z, Kong X, Xia H, Wang C, Xiang H. A Drive-By Frequency Identification Method for Simply Supported Railway Bridges Using Dynamic Responses of Passing Two-Axle Vehicles[J]. Journal of Bridge Engineering, 2021, 26(11): 04021078.
Zhang Z W, Xiang H J, Tang L H. Modeling, analysis and comparison of four charging interface circuits for piezoelectric energy harvesting[J]. Mechanical Systems and Signal Processing, 2021, 152: 107476.
Zhao X J, Xiang H J, Shi Z F. Piezoelectric energy harvesting from vehicles induced bending deformation in pavements considering the arrangement of harvesters[J]. Applied Mathematical Modelling, 2020, 77(1): 327-340.
Cheng Z B, Shi Z F, Palermo A, Xiang H J, Guo W, Marzani A. Seismic vibrations attenuation via damped layered periodic foundations[J]. Engineering Structures, 2020, 211: 110427.
Zhang Z W, Tang L H, Xiang H J. Piezoelectric Energy Harvesting from Bridge Vibrations Using Different Models for Moving Vehicles[J]. Journal of Aerospace Engineering, 2019, 32: 04018141.
Huang J K, Liu X W, Chen X H, Xiang H J. Multiple flexural-wave attenuation zones of periodic slabs with cross-like holes on an arbitrary oblique lattice: Numerical and experimental investigation[J]. Journal of Sound and Vibration, 2018, 437: 135-149.
Zhang Z W, Xiang H J, Shi Z F, Zhan J W. Experimental investigation on piezoelectric energy harvesting from vehicle bridge coupling vibration[J]. Energy Conversion and Management, 2018, 163: 169-179.
Xiang H J, Zhang Z W, Shi Z F, Li H. Reduced-order modeling of piezoelectric energy harvesters with nonlinear circuits under complex conditions[J]. Smart Materials and Structures, 2018, 27: 045004.
Zhang Z W, Xiang H J, Shi Z F. Theoretical Modeling on Piezoelectric Energy Harvesting from Bridges Considering Roadway Surface Irregularities[M]//WANG L B, LING J M, LING J M, et al. 2018:673-684.
Pu X B, Shi Z F, Xiang H J. Feasibility of ambient vibration screening by periodic geofoam-filled trenches[J]. Soil Dynamics and Earthquake Engineering, 2018, 104: 228-235.
Zhang Z W, Xiang H J, Shi Z F. Mechanism exploration of piezoelectric energy harvesting from vibration in beams subjected to moving harmonic loads[J]. Composite Structures, 2017, 179: 368-376.
Wang X F, Shi Z F, Wang J J, Xiang H J. A stack-based flex-compressive piezoelectric energy harvesting cell for large quasi-static loads[J]. Smart Materials and Structures, 2016, 25: 055005.
Zhang Z W, Xiang H J, Shi Z F. Modeling on piezoelectric energy harvesting from pavements under traffic loads[J]. Journal of Intelligent Material Systems and Structures, 2016, 27(4): 567-578.
Wang J J, Shi Z F, Xiang H J, Song G B. Modeling on energy harvesting from a railway system using piezoelectric transducers[J]. Smart Materials and Structures, 2015, 24(10): 105017.
Liu X N, Shi Z F, Xiang H J, Mo Y L. Attenuation zones of periodic pile barriers with initial stress[J]. Soil Dynamics and Earthquake Engineering, 2015, 77: 381-390.
Shi Z, Cheng Z, Xiang H. Seismic isolation foundations with effective attenuation zones[J]. Soil Dynamics and Earthquake Engineering, 2014, 57: 143-151.
Xiang H J, Wang J J, Shi Z F, Zhang Z W. Theoretical analysis of piezoelectric energy harvesting from traffic induced deformation of pavements[J]. Smart Materials and Structures, 2013, 22(9): 095024.
Wang J J, Shi Z F, Xiang H J. Electromechanical Analysis of Piezoelectric Beam-Type Transducers With Interlayer Slip[J]. IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, 2013, 60(8): 1768-1776.
Cheng Z B, Shi Z F, Mo Y L, Xiang H J. Locally resonant periodic structures with low-frequency band gaps[J]. Journal of Applied Physics, 2013, 114: 0335323.
Cheng Z B, Yan Y Q, Menq F Y, Mo Y L, Xiang H J, Shi Z F, Stokoe K H. 3D Periodic Foundation-based Structural Vibration Isolation[M]//AO S I, GELMAN L, HUKINS D, et al. Lecture Notes in Engineering and Computer Science. 2013:1797-1802.
Xiang H J, Shi Z F, Wang S J, Mo Y L. Periodic materials-based vibration attenuation in layered foundations: experimental validation[J]. Smart Materials and Structures, 2012, 21: 11200311.
Xiong C, Shi Z F, Xiang H J. Attenuation of Building Vibration Using Periodic Foundations[J]. Advances in Structural Engineering, 2012, 15(8): 1375-1388.
Bao J, Shi Z F, Xiang H J. Dynamic Responses of a Structure with Periodic Foundations[J]. Journal of Engineering Mechanics, 2012, 138(7): 761-769.
Xiang H J, Shi Z F. Vibration attenuation in periodic composite Timoshenko beams on Pasternak foundation[J]. Structural Engineering and Mechanics, 2011, 40(3): 373-392.
Xiang H J, Shi Z F. Analysis of flexural vibration band gaps in periodic beams using differential quadrature method[J]. Computers & Structures, 2009, 87(23-24): 1559-1566.
Zhao S, Shi Z F, Xiang H J. The Primary Resonance of Laminated Piezoelectric Rectangular Plates[J]. IEEE Transactions on Ultrasonics Ferroelectrics and Frequency Control, 2009, 56(11): 2522-2529.
Xiang H J, Shi Z F. Static analysis of a multilayer piezoelectric actuator with bonding layers and electrodes[J]. Smart Structures and Systems, 2009, 5(5): 547-564.
Xiang H J, Shi Z F. Static analysis for functionally graded piezoelectric actuators or sensors under a combined electro-thermal load[J]. European Journal of Mechanics a-Solids, 2009, 28(2): 338-346.
Xiang H J, Yang J. Free and forced vibration of a laminated FGM Timoshenko beam of variable thickness under heat conduction[J]. Composites Part B-Engineering, 2008, 39(2): 292-303.
Xiang H J, Shi Z F. Static analysis for multi-layered piezoelectric cantilevers[J]. International Journal of Solids and Structures, 2008, 45(1): 113-128.
Xiang H, Shi Z. Electrostatic analysis of functionally graded piezoelectric cantilevers[J]. Journal of Intelligent Material Systems and Structures, 2007, 18(7): 719-726.
Shi Z, Zhang T, Xiang H. Exact solutions of heterogeneous elastic hollow cylinders[J]. Composite Structures, 2007, 79(1): 140-147.
Yang J, Xiang H J. Thermo-electro-mechanical characteristics of functionally graded piezoelectric actuators[J]. SMART MATERIALS & STRUCTURES, 2007, 16(3): 784-797.
Yang J, Xiang H J. A three-dimensional finite element study on the biomechanical behavior of an FGBM dental implant in surrounding bone[J]. Journal of Biomechanics, 2007, 40(11): 2377-2385.
Shi Z F, Xiang H J, Spencer B F. Exact analysis of multi-layer piezoelectric/composite cantilevers[J]. Smart Materials and Structures, 2006, 15(5): 1447-1458.
Xiang HJ, Shi ZF, Zhang TT. Elastic analyses of heterogeneous hollow cylinders[J]. Mechanics Research Communications, 2006, 33(5): 681-691.

专著/译著

石志飞, 程志宝, 向宏军. 周期结构：理论及其在隔震减振中的应用.科学出版社, 2017.6

专利

一种高性能轨道交通压电俘能器.
一种热塑性塑料玻纤挤出复合轨枕及其制备方法.
一种多稳态调谐质量压电俘能器.
一种加筋复合轨枕及其制备方法.
一种调谐质量压电俘能器及其制造方法.
一种预制有2-2型水泥基压电俘能器的压电智能混凝土轨枕.
一种剪切型压电俘能器及其制造方法.
钢筋混凝土周期性减震结构及施工方法.

软件著作权

获奖与荣誉

学术类：

教育部高校科研优秀成果自然科学二等奖
国家自然科学基金优秀青年基金
教育部新世纪优秀人才支持计划
北京市青年英才计划
北京交通大学卓越百人计划

教学类：

北京市青年教学名师
宝钢优秀教师
北京交大课堂教学教风标兵
全国结构力学青年教师讲课竞赛一等奖
智瑾优秀青年教师
北京市教学成果一等奖（参加）

思政类：

全国高校“双带头人”教师党支部书记
北京市优秀共产党员
北京交大五四奖章
北京交通大学优秀共产党员标兵

社会兼职

土木工程学会先进工程材料分会，理事
Engineering Research Express、Advances in Computational Design、土木与环境工程学报、路基工程，编委
International Journal of Smart and Nano Materials、复合材料学报，青年编委
北京交大建筑勘察设计院，执行董事、法人
50余本国内外期刊的审稿人