个人资料
个人简介张增平,男,陕西蓝田人,教授,硕、博导。西北工业大学、加州大学欧文分校联合培养博士,2008年获材料学博士学位,研究方向为复合材料。长安大学交通运输博士后流动站博士后出站。注册公路检测工程师(公路、材料)。目前在长安大学公路学院道路工程系从事道路工程领域的教学与科研工作。2017年4月-2018年8月期间任西安经济技术开发区管委会副主任(挂职)。 学术成果详情见学术主页: https://loop.frontiersin.org/people/1765264/overview; https://www.researchgate.net/profile/Zengping-Zhang-3 社会职务Journal of Polymer Materials(SCI),Associate Editor-in-chief(副主编); Frontier in Built Environment(ESCI),副主编; Sustainability(SCI),编委; The Baltic Journal of Road and Bridge Engineering(SCI),编委; Advances in Civil Engineering(SCI),编委; Advances in Materials Science and Engineering(EI),编委; 《中国胶粘剂》、《聚氨酯工业》、《粘接》编委; 美国化学学会(ACS)会员; 国家自然科学基金通讯评审专家; 河南、江西、重庆科技项目通信评审专家; “两湾”产业融合科技创新智库专家; Carbohydrate Polymers、Colloid and Surface A、Materials Chemistry and Physics、Journal of Applied Polymer Science、Polymer Composites、Construction and Building Materials、International Journal of Pavement Research and Technology、中国公路学报、材料导报、交通运输工程学报、长安大学学报、空军工程大学学报、江苏大学学报等国内外期刊审稿专家。 研究领域主要研究领域为道路工程材料组成、结构与性能关系研究。聚焦开展面向路面工程材料的学科交叉研究。研究方向主要包括: 1.聚合物改性沥青及混凝土材料;(聚氨酯、环氧等) 2.道路交通新材料研究与开发; 3.材料微观结构对性能的影响; 4.路面材料分子动力学计算研究; 5.高性能工程用填缝、灌缝粘接材料; 6.沥青材料改性剂的合成与应用性能; 7.纳米材料的制备及在道路交通领域的应用; 团队已毕业硕士20余名,课题组目前在读博士生2名、硕士生10名。欢迎对道路工程新材料研究、开发和应用感兴趣的公路工程、土木工程、材料类、化学类等专业背景的学生加入研究团队攻读硕士或博士学位。 开授课程本科生:《道路工程材料》;《专业英语》;《现代科技英语》;《沥青及其混合料改性新技术》 研究生:《聚合物及其改性道路材料》 科研项目主持项目: 国家自然科学基金基于层状硅酸盐有机化技术的沥青纳米复合及其改性机理(2013.1-2015.12); 陕西省重点研发计划,聚氨酯分子结构设计及其改性沥青研究(2024.1-2025.12); 陕西省交通厅科研项目,钢混组合梁桥面铺装用聚氨酯(PU)改性沥青及其混合料研究。(2018.1- 2020.12); 塑料卫生与安全质量评价技术北京市重点实验室开放课题(2020.7-2021.7); 中国博士后科学基金一等资助(2009.9-2011.9); 陕西省自然科学基金西项目“有机化蒙脱土/沥青纳米复合材料的结构与性能研究”(2015.1-2016.12); 企业横向项目,新型路面灌封胶开发,20万; 企业横向项目,重交通沥青路面研究(2023.7-2024.7),20万; 企业横向项目,新型高性能沥青再生剂研究(2023.6-2025.6),108万。 参与项目: 国家自然科学基金面上项目1项。 论文[67]Hao Liu, Zengping Zhang*, Suyu Zhang, et al,Study on the effect of soft segment length on the performance of polyether-based polyurethane modified asphalt,International Journal of Adhesion and Adhesives,130(2024).103642 [66]Yongming Wei, Zengping Zhang*, Hao Liu, et al, Study on the anti-aging properties of organic attapulgite (OATT) and polyurethane (PU) composite-modified asphalt, International Journal of Pavement Engineering, 25(2024).2301456 [65]Z. Zhang*, Z. Wang, S. Zhang, et al, Experimental studies and molecular dynamics simulation of the compatibility between thermoplastic polyurethane elastomer (TPU) and asphalt, Construction and Building Materials 411 (2024). [64]Zengping Zhang, Hao Liu, Xiaoyi Ban, et al, Thermosetting resin modified asphalt: A comprehensive review, Journal of Traffic and Transportation Engineering (English Edition), 2023,10(6): 1001-1036 [63]X. Ban, Z. Zhang*, P. Chang, S. Zhang, H. Liu, Y. Liang, Y. Chen, The Performance and Distribution of Polyurethane-Modified Asphalt That Exhibits Different Molecular Weights, Sustainability 15(8) (2023) 6627-6627. [62]H. Liu, Z. Zhang*, Z. Wang, J. Sun, Y. Wei, D. Zhang, Preparation and properties of flame-retardant asphalt containing polyurethane and eco-friendly flame retardants, Construction and Building Materials 375 (2023). [61] Z. Mi, Y. Hu, Q. Li, Y. Wang, H. Zhang, Z. Zhang, An inverse analysis method for determining tensile softening relationship of concrete considering local response, Construction and Building Materials 394 (2023). [60] J. Sun, S. Zhang, Y. Liu, Z. Zhang*, X. Liu, Z. Zhang, X. Ban, Construction Technology and Pavement Performance of Dry-Mix Polyurethane Modified Asphalt Mixtures: A Case Study, Sustainability 15(18) (2023) 13635-13635. [59]刘虓嵩,张增平,郭茵霄等.用于公路工程的聚氨酯密封胶研究进展[J].中国胶粘剂,2023,32(09):49-57. [58]温富升,张增平,孙佳等.生物基固化剂在桥面铺装用环氧沥青中的应用[J].热固性树脂,2023,38(03):44-48. [57]张增平,王力,朱友信等.多亚甲基多苯基多异氰酸酯(PAPI)型聚氨酯改性沥青的流变性能[J].材料科学与工程学报,2023,41(02):235-240. [56]张增平,陈俐企,黄婷等.用于排水沥青路面的高黏度改性沥青的制备及性能[J].长安大学学报(自然科学版),2023,43(01):1-9. [55] L. Wang, Z. Zhang*, J. Sun, H. Liu, Y. Wei, D. Zhang, Z. Wang, Investigation on the High- and Low-Temperature Performance of Organic Rectorite and Polyurethane Composite-Modified Asphalt Binder, Journal of Materials in Civil Engineering 35(9) (2023). [54] Z. Wang, G. Hou, J. Xie, Z. Zhang, X. Zhang, J. Cai, Degradable bio-based fluorinated epoxy resin with excellent flame-retardant, dielectric, hydrophobic, and mechanical properties, Advanced Composites and Hybrid Materials 6(4) (2023). [53] Z. Zhang*, T. Huang, J. Sun, Z. Wang, L. Wang, X. Li, H. Liu, D. Zhang, Laboratory Study and Molecular Dynamics Simulation of High- and Low-Temperature Properties of Polyurethane-Modified Asphalt, Journal of Materials in Civil Engineering 35(8) (2023). [52] Z. Zhang*, Y. Wei, X. Liu, Y. Guo, H. Liu, J. Sun, X. Yu, S. Kan, Combined modification of asphalt with organic attapulgite (OATT) and polyurethane (PU): preparation, properties and modification mechanisms, Construction and Building Materials 406 (2023). [51]L. Chen, Z. Zhang, Z*. Wang, H. Liu, D. Zhang, J. Sun, Using SBS terpene-styrene resin blends as a novel high-viscosity asphalt modifier, Journal of Applied Polymer Science 140(4) (2022). [50]Z. Guo, P. Ren, Z. Zhang, Z. Dai, Z. Lu, Y. Jin, F. Ren, Fabrication of carbonized spent coffee grounds/graphene nanoplates/cyanate ester composites for superior and highly absorbed electromagnetic interference shielding performance, Journal of Materials Science and Technology 102 (2022) 123-131. [49] T. Huang, Z. Zhang*, L. Wang, J. Sun, Z. Wang, H. Liu, L. Chen, Study on the compatibility between polyurethane and asphalt based on experiment and molecular dynamics simulation, Case Studies in Construction Materials 17 (2022). [48] M. Jia, A. Sha, J. Lin, Z. Zhang, B. Qi, D. Yuan, Polyurethane asphalt binder: a promising candidate for steel bridge deck-paving material, International Journal of Pavement Engineering 23(11) (2022) 3920-3929. [47]孙佳,张增平,王封等.聚氨酯/环氧树脂复合改性沥青性能研究与组成优化[J].热固性树脂,2022,37(01):1-4+11. [46] M. Jia, Z. Zhang*, N. Yang, B. Qi, W. Wang, Z. Huang, J. Sun, F. Luo, T. Huang, Performance Evaluation of Thermosetting and Thermoplastic Polyurethane Asphalt Mixtures, Journal of Materials in Civil Engineering 34(6) (2022). [45] H. Liu, Z. Zhang*, Y. Zhu, J. Sun, L. Wang, T. Huang, L. Chen, Modification of asphalt using polyurethanes synthesized with different isocyanates, Construction and Building Materials 327 (2022). [44] J. Sun, Z. Zhang*, L. Wang, H. Liu, X. Ban, J. Ye, Investigation on the epoxy/polyurethane modified asphalt binder cured with bio-based curing agent: Properties and optimization, Construction and Building Materials 320 (2022). [43] J. Sun, Z. Zhang*, J. Ye, H. Liu, Y. Wei, D. Zhang, X. Li, Preparation and properties of polyurethane/epoxy-resin modified asphalt binders and mixtures using a bio-based curing agent, Journal of Cleaner Production 380 (2022). [42] Z. Zhang*, L. Chen, J. Peng, J. Sun, D. Zhang, X. Li, F. Wen, H. Liu, Preparation and properties of a novel high-viscosity modified bitumen, Construction and Building Materials 344 (2022). [41] Z. Zhang*, J. Sun, L. Wang, Y. Zhu, H. Liu, T. Huang, Z. Huang, Laboratory Investigation of PPG-TDI Polyurethane-Modified Asphalt Binders and Mixtures, Journal of Materials in Civil Engineering 34(9) (2022). [40] Z. Guo, P. Ren, Z. Zhang, Z. et al, Simultaneous realization of highly efficient electromagnetic interference shielding and human motion detection in carbon fiber felt decorated with silver nanowires and thermoplastic polyurethane, Journal of Materials Chemistry C 9(21) (2021) 6894-6903. [39]王力,张增平,朱友信等.PAPI型聚氨酯改性沥青性能与微观机理[J].硅酸盐通报,2021,40(12):4158-4166. [38]张增平,黄婷,朱友信等.PU软段结构类型对PU改性沥青性能的影响[J].长安大学学报(自然科学版),2021,41(06):1-9. [37] Z. Zhang*, M. Jia, Evaluating the effect of organic reagents on short-term aging resistance of the organic rectorite asphalt by multi-indicators, Road Materials and Pavement Design 22(1) (2021) 215-229. [36] Z. Zhang*, J. Sun, Z. Huang, F. Wang, M. Jia, W. Lv, J. Ye, A laboratory study of epoxy/polyurethane modified asphalt binders and mixtures suitable for flexible bridge deck pavement, Construction and Building Materials 274 (2021). [35] Z. Zhang*, J. Sun, M. Jia, X. Ban, L. Wang, L. Chen, T. Huang, H. Liu, Effects of Polyurethane Thermoplastic Elastomer on Properties of Asphalt Binder and Asphalt Mixture, Journal of Materials in Civil Engineering 33(3) (2021). [34] M. Su, C. Si, Z. Zhang, H. Zhang, Molecular dynamics study on influence of Nano-ZnO/SBS on physical properties and molecular structure of asphalt binder, Fuel 263 (2020). [33] Z. Zhang*, J. Sun, M. Jia, B. Qi, H. Zhang, W. Lv, Z. Mao, P. Chang, J. Peng, Y. Liu, Study on a thermosetting polyurethane modified asphalt suitable for bridge deck pavements: Formula and properties, Construction and Building Materials 241 (2020). [32]张增平,孙佳,王封等.环氧树脂/聚氨酯复合改性沥青及其混合料性能研究[J].功能材料,2020,51(12):12198-12203+12214. [31]张增平,彭江,朱永彪等.聚氨酯改性沥青的制备及流变性能研究[J].聚氨酯工业,2020,35(05):15-17. [30]M. Jia, A. Sha, Z. Zhang, J. Li, D. Yuan, W. Jiang, Effect of organic reagents on high temperature rheological characteristics of organic rectorite modified asphalt, Construction and Building Materials 227 (2019). [29]M. Jia, Z. Zhang*, H. Liu, B. Peng, H. Zhang, W. Lv, Q. Zhang, Z. Mao, The synergistic effect of organic montmorillonite and thermoplastic polyurethane on properties of asphalt binder, Construction and Building Materials 229 (2019). [28]M. Jia, Z. Zhang*, L. Wei, J. Li, D. Yuan, X. Wu, Z. Mao, High- and low-temperature properties of layered silicate-modified bitumens: View from the nature of pristine layered silicate, Applied Sciences (Switzerland) 9(17) (2019). [27]M. Jia, Z. Zhang*, L. Wei, X. Wu, X. Cui, H. Zhang, W. Lv, Q. Zhang, Study on properties and mechanism of organic montmorillonite modified bitumens: View from the selection of organic reagents, Construction and Building Materials 217 (2019) 331-342. [26]D. Luo, A. Khater, Y. Yue, M. Abdelsalam, Z. Zhang, Y. Li, J. Li, D.T. Iseley, The performance of asphalt mixtures modified with lignin fiber and glass fiber: A review, Construction and Building Materials 209 (2019) 377-387. [25] Z. Zhang*, M. Jia, W. Jiao, B. Qi, H. Liu, Physical properties and microstructures of organic rectorites and their modified asphalts, Construction and Building Materials 171 (2018) 33-43. [24] C. Fang, C. Wu, J. Hu, R. Yu, Z. Zhang, L. Nie, S. Zhou, X. Mi, Pavement properties of asphalt modified with packaging-waste polyethylene, Journal of Vinyl and Additive Technology 20(1) (2014) 31-35. [23]Z. Zhang, G. Liang, X. Wang, Epoxy-functionalized polyhedral oligomeric silsesquioxane/cyanate ester resin organic-inorganic hybrids with enhanced mechanical and thermal properties, Polymer International 63(3) (2014) 552-559. [22] C. Fang, C. Wu, R. Yu, Z. Zhang, M. Zhang, S. Zhou, Aging properties and mechanism of the modified asphalt by packaging waste polyethylene and waste rubber powder, Polymers for Advanced Technologies 24(1) (2013) 51-55. [21] Z. Zhang, G. Liang, X. Wang, S. Adhikari, J. Pei, Curing behavior and dielectric properties of amino-functionalized polyhedral oligomeric silsesquioxane/cyanate ester resin hybrids, High Performance Polymers 25(4) (2013) 427-435. [20] Z. Zhang, G. Liang, C. Fang, J. Pei, S. Chen, Curing octaepoxysilsesquioxane with different curing agents, Journal of Applied Polymer Science 125(3) (2012) 2281-2288. [19] Z. Zhang, J. Pei, G. Liang, L. Yuan, Methyl silsesquioxane/cyanate ester resin organic-inorganic hybrids with low dielectric constant, Journal of Applied Polymer Science 121(2) (2011) 1004-1012. [18] P. Ren, Z. Zhang, L. Xie, F. Ren, Y. Jin, Y. Di, C. Fang, Hybrid effect on mechanical properties of M40-T300 carbon fiber reinforced Bisphenol A Dicyanate ester composites, Polymer Composites 31(12) (2010) 2129-2137. [17] C. Fang, M. Zhang, Z. Zhang, S. Zhou, UV-aging resistance of packaging waste PE modified asphalts, Polymer - Plastics Technology and Engineering 48(9) (2009) 945-949. [16] P. Ren, G. Liang, Z. Zhang, Erratum: Study on glass fabric reinforced polytetrafluoroethylene composites infused with melted cyanate ester resin (Journal of Reinforced Plastics and Composites (2009) 28 (2221-2230)), Journal of Reinforced Plastics and Composites 28(18) (2009) 2303-2303. [15] C. Fang, T. Li, Z. Zhang, D. Jing, Modification of asphalt by packaging waste-polyethylene, Polymer Composites 29(5) (2008) 500-505. [14] C. Fang, T. Li, Z. Zhang, X. Wang, Combined modification of asphalt by waste PE and rubber, Polymer Composites 29(10) (2008) 1183-1187. [13] Z. Zhang, A. Gu, G. Liang, P. Ren, J. Xie, X. Wang, Thermo-oxygen degradation mechanisms of POSS/epoxy nanocomposites, Polymer Degradation and Stability 92(11) (2007) 1986-1993. [12]Z. Zhang, G. Liang, T. Lu, Synthesis and characterization of cage octa(aminopropylsilsesquioxane), Journal of Applied Polymer Science 103(4) (2007) 2608-2614. [11] Z. Zhang, G. Liang, P. Ren, J. Wang, Thermodegradation kinetics of epoxy/DDS/POSS system, Polymer Composites 28(6) (2007) 755-761. [10] Z. Zhang, G. Liang, P. Ren, J. Wang, Curing behavior of epoxy/POSS/DDS hybrid systems, Polymer Composites 29(1) (2008) 77-83. [9] Z. Zhang, G. Liang, J. Wang, P. Ren, Epoxy/POSS organic-inorganic hybrids: Viscoelastic, mechanical properties and micromorphologies, Polymer Composites 28(2) (2007) 175-179. [8] Z. Zhang, G. Liang, X. Wang, The effect of POSS on the thermal properties of epoxy, Polymer Bulletin 58(5-6) (2007) 1013-1020. [7] Z. Zhang, X. Wang, J. Xie, G. Liang, Using octa(aminpropyl)silsesquioxane as the curing agent for epoxy resin, Journal of Reinforced Plastics and Composites 26(16) (2007) 1665-1670. [6] P. Ren, G. Liang, Z. Zhang, T. Lu, ZnO whisker reinforced M40/BADCy composite, Composites Part A: Applied Science and Manufacturing 37(1) (2006) 46-53. [5] G. Liang, P. Ren, Z. Zhang, T. Lu, Effect of the epoxy molecular weight on the properties of a cyanate ester/epoxy resin system, Journal of Applied Polymer Science 101(3) (2006) 1744-1750. [4] G. Liang, Z. Zhang, J. Yang, Study on properties of low dieletric loss resin matrix, Polymer Bulletin 58(5-6) (2007) 1021-1029. [3] G. Liang, Z. Zhang, J. Yang, X. Wang, BMI based composites with low dielectric loss, Polymer Bulletin 59(2) (2007) 269-278. [2] P. Ren, G. Liang, Z. Zhang, Epoxy-modified cyanate ester resin and its high-modulus carbon-fiber composites, Polymer Composites 27(4) (2006) 402-409. [1] P. Ren, G. Liang, Z. Zhang, Influence of epoxy sizing of carbon-fiber on the properties of carbon fiber/cyanate ester composites, Polymer Composites 27(5) (2006) 591-598. 1.《聚合物及其改性道路材料》,人民交通出版社,张增平主编,2021年7月。 2.《聚氨酯改性沥青及其混合料理论、技术与工程应用》,哈尔滨工业大学出版社,张增平著,2022年8月。 3.《纳米金属粉——制备、表征和在含能体系中的应用》(Metal nanopowders:production, characterization and energetic applications)(译著),国防工业出版社,庞维强、樊学忠、张增平译。2016年12月。 科技成果专利: 1)一种玻璃纤维增强热固性树脂基复合材料的制备方法,专利号:ZL 201010500234.4 产业化产品: HVS系列高粘改性剂颗粒(应用于透水沥青路面)
荣誉奖励 2016年陕西省科学技术二等奖; 2012年长安创先争优优秀共产党员; 2014年长安大学第八届“挑战杯”大学生创业计划竞赛银奖,指导教师; 2016年长安大学第九届“挑战杯”大学生创业计划竞赛金奖,指导教师; 2016年西安高新“创青春”陕西省大学生创业大赛银奖,指导教师; 2022年“建行”第八届中国国际“互联网+”大学生创新创业大赛铜奖,指导教师 2022年长安大学“挑战杯”大学生创业计划竞赛金奖,指导教师; 2023年陕西省交通运输科学技术三等奖(排名第2) 工作经历2016年12月至今 长安大学公路学院道路工程系 教授 2017年4月-2018年8月 西安经济技术开发区管委会 副主任(挂职) 2011年11月-2016年12月 长安大学公路学院道路所 副教授 2008年10月-2009年10月 加州大学欧文分校(University of California, Irvine)化学系 访问学者 2008年10月-2011年11月 长安大学公路学院道路系 讲师 |
EHP系列环保型石油沥青密封胶系列(路面裂缝、桥梁伸缩缝等填缝和密封)