王建 教授

王建博士 教授

jian.wang@mail.buct.edu.cn; wjj_0107@163.com

个人概况：

2010年6月毕业于北京化工大学；2009年9月，获国家留学基金委资助，在Universityof Wisconsin –Madison聚合物工程中心工作；2010年9月回国就职于北京理工大学；2017年7月获德国洪堡基金会资助，在RWTHAachen University塑料加工研究院工作；2020年8月回国就职于北京化工大学。

以聚合物及其复合材料先进成形技术为研究方向，聚焦塑料制品成形方法与形性调控机理的共性科学问题，以“数据精确-模型可靠-控制精准”为目标，开展了“材料特性测定-数学模型建立-制品控形与控性”的研究工作，为高质量塑料制品高效批量制备提供理论依据和技术支持。以第一/通讯作者在AdvancedComposites and Hybrid Materials、Carbon、CompositesScience and Technology、CompositesPart A、CompositesStructure、CompositesCommunications、Materialsand Design、PolymerTesting等期刊发表论文100余篇，获授权国家专利64件和软件著作权5件。主编《SomeCritical Issue for Injection Molding》、《RheologicalMeasurement Techniques and Analysis Methods》《SurfaceEngineering - Foundational Concepts, Techniques andApplications》(InTech)，主译《注塑模具设计工程》(机械工业出版社\Hanser)，参写《Polypropylene- Based Biocomposites and Bionanocomposites》(Wiley)、《ReferenceModule in Materials Science and MaterialsEngineering》(Elsevier)、《高分子材料模塑成型》、《注射成型新技术》、《高分子材料注射成型CAE理论及应用》等。

主持国家自然科学基金（青年和面上项目）、国家重点研发计划子课题、国际合作（荷兰阿克苏诺贝尔）等项目30余项。曾获北京市科学技术进步二等奖、中国石油和化学工业联合会科技进步二等奖、国家科学技术进步二等奖、德国IKV塑料加工研究院优秀贡献奖、德国SFB国际合作研究中心优秀论文奖、全国三好学生等。

入选德国亚历山大·冯·洪堡基金会资深学者、北京化工大学青年英才百人、中国塑料加工工业协会专家、中国塑料加工工业协会注塑制品专委会理事、中国塑料机械工业协会委员、国家科技专家库专家、国家自然科学基金通讯评审专家、教育部学位中心学位论文评审人，国际PPS聚合物加工协会、国际PES塑料工程师协会、中国机械工程学会、中国化学会、美国ACS化学会会员，Polymers、Frontiersin Materials、Journalof Research Update in Polymer Science、InTech编委和30余个国内外学术期刊审稿专家。

教育背景：

2001.09-2005.06北京化工大学学士

2005.09-2010.06北京化工大学硕博连读

2009.09-2010.09美国威斯康辛大学麦迪逊分校联合培养博士

工作履历：

2010.09-2016.06北京理工大学讲师

2016.07-2018.08北京理工大学副教授

2017.11-2020.08德国亚琛工业大学洪堡资深研究员

2018.08-至今北京化工大学 教授

教学工作：

主讲《机械设计》、《机械设计基础课程设计》，曾主讲《化工设备与机械》、《计算机实践》本科生课程和《高等流体力学》、《高等化工数学》研究生课程

代表性论文：

1. Cheng Y, WangJ.*,Shao M, Liang Y, Li H. (2025) Hybrid combinations of graphenenanoplatelet, carbon nanotube, and carbon blackfor tailored mechanical and triboelectric properties inpolypropylene fibers, AdvancedComposites and Hybrid Materials.8, 259.

2. WangJ.*,Li H., Li F., Fan C., Liu T., Wang D. (2025) Insert-injectionmoulding and post-thermal treatment of hybrid continuous anddiscontinuous glass-fibre-reinforced polyamide composite products,Composites:Part A,188, 108534.

3. WangJ.*,He Q., Huang S., Cheng Y., Li H., Chen D. (2025) Mechanicalrecycling and performance characterisation of insert-injectionmoulded homo-polypropylene single-polymer composites and foams,CompositesCommunications,53, 102176.

4. WangJ.*,Martin-Doñate C., Cui H., Liang Y., Li H. (2025) Editorial:Injection molding of polymeric and composite materials, Frontiersin Materials,11:1534575.

5. WangJ.*,Liu T., Zheng K., Liu H., Cui H., Li H. (2024) Local thermal warpagedeformation of polypropylene injection molded flat part and neuralnetwork prediction model, Frontiersin Materials10.3389/fmats. 2024.1421546. (Q2, IF3.2)

6. WangJ.*,He J., Li H., Fang K. (2023) Qualitative characterization ofresidual stress of injection molded polycarbonate goggles based onphotoelasticity and digital image processing technique, Frontiersin Materials10.3389/fmats.2023.1242721.

7. WangJ.*,Zheng K., Hu X., Long Z., Chen K. (2023): Application of twin-screwextruder with ultra-high length-to-diameter ratio in dry-jet wetspinning process of polyacrylonitrile nascent fibers, Industrial& Engineering Chemistry Research62, 21, 8477-8488.

8. HeQ., Yang W., WangJ.*,Ren F., Wang D., Li F., Shi Z. (2023): Direct in-mold impregnationof glass fiber fabric by polypropylene with supercritical nitrogenin microcellular injection molding process, Polymers15(4), 875.

9. WangJ.*,Zhang Q., Cheng Y., Song F., Ding Y., Shao M. (2022): Self-reinforced composites based on polypropylene fiber and graphenenano-platelets/polypropylene film, Carbon.189: 586.

10. WangJ.*,Mao Q., Jiang N., Chen J. (2022):  Effects of injection moldingparameters on properties of insert-injection molded polypropylenesingle-polymer composites, Polymers.14(1): 23.

11. WangJ.*,Song F., Yu M. (2022): Unidirectional continuous fiber-reinforcedpolypropylene single-polymer composites prepared byextrusion-calendering process, Journalof Thermoplastic Composite Materials.35(3):303-319.    

12. WangJ.*,Hopmann C., Liu B., Lockner Y. (2021):  Prediction of specificvolume of polypropylene at high cooling rates by artificial neuralnetworks, Industrial& Engineering Chemistry Research.60, 14434.

13. WangJ.*,Hopmann C., Kahve C., Hohlweck T., Alms J. (2020):  Measurement ofspecific volume of polymers under simulated injection moldingprocesses, Materialsand Design.196, 109136.    

14. WangJ.*,Song F., Ding Y., Shao M. (2020):  The incorporation of graphene toenhance mechanical properties of polypropylene self-reinforcedpolymer composites, Materialsand Design.195, 109073.

15. WangJ.*,Hopmann C., Röbig M., Hohlweck T., Kahve C., Alms J. (2020): Continuous two-domain equations of state for the description of thepressure-specific volume-temperature behavior of polymers, Polymers.12(2): 0-409.

16. WangJ.*,Hopmann C., Röbig M., Hohlweck T., Alms J. (2020):  Modeling ofpressure-specific volume-temperature behavior of polymersconsidering the dependence of cooling and heating processes,Materialsand Design.196, 109110.

17. AlmsJ.*, Hopmann C., WangJ.*,Hohlweck T. (2020):  Non-isothermal crystallisation kinetics ofpolypropylene at high cooling rates and comparison to the continuoustwo-domain pvT model, Polymers.12(7): 1515.    

18. WangJ.*,Hopmann C., Schmitz M., Hohlweck T. (2020):  Process dependence ofpressure-specific volume-temperature measurement for amorphouspolymer: Acrylonitrile-butadiene-styrene, PolymerTesting.81, 106232.    

19. WangJ.*,Hopmann C., Schmitz M., Hohlweck T., Wipperfürth J. (2019):Modeling of pvT behavior of semi-crystalline polymer based on thetwo-domain Tait equation of state for injection molding. Materialsand Design.183, 108149.

20. WangJ.*,Hopmann C., Schmitz M., Hohlweck T. (2019): Influence of measurementprocesses on pressure-specific volume-temperature relationships ofsemi-crystalline polymer: Polypropylene. PolymerTesting.78: 105992.

21. WangJ.*,Yang L. (2019): Internal circulation clamping system withsupplementary volume for small and medium types of two-plateninjection molding machine. AdvancedIndustrial and Engineering Polymer Research.2: 116-120.

22. WangJ.*,Wang S., Du Z., Peng J. (2018): Properties of insert injectionmolded polypropylene single-polymer composites with uniaxial fibers.MacromolecularSymposia.378, 1600154: 1-7.

23. WangJ.*,Chen D. (2018): Flexural properties and morphology ofmicrocellular-insert injection molded all-polypropylene compositefoams. CompositeStructure.187: 403-410.

24. WangJ.*,Du Z. Lian T. (2018): Extrusion–Calendering process ofsingle-polymer composites based on polyethylene，PolymerEngineering and Science.58 (12): 2156-2165.

25. WangJ.*,Chen D., Wang S., Du Z., Jiang N., Peng J. (2018): Insert injectionmolding of low-density polyethylene single-polymer compositesreinforced with ultrahigh-molecular-weight polyethylenefabric，Journalof Thermoplastic Composite Materials.31(8): 1013-1028.

26. WangJ.*,Chen D. (2016): Microcellular polypropylene single-polymercomposites prepared by insert-microcellular injection molding.Composites:Part A.90: 567-576.

27. WangJ.*,Wang S., Chen D. (2015): Development and characterization of insertinjection moulded polypropylene single-polymer composites withsandwiched woven fabric. CompositesScience and Technology.117: 18-25.

28. MaoQ., Wyatt T.P., Chen J., WangJ.*(2015): Insert injection molding of high-density polyethylenesingle-polymer composites. PolymerEngineering and Science.11: 2448-2456.

29. WangJ.*,Chen J., Dai P., Wang S., Chen D. (2015): Properties ofpolypropylene single-polymer composites produced by the undercoolingmelt film stacking method. CompositesScience and Technology.107: 82-88.

30. MaoQ., Hong Y., Wyatt T.P., Chen J., Wang Y., WangJ.*,Yao D.* (2015): Insert injection molding of polypropylenesingle-polymer composites. CompositesScience and Technology.106: 47-54.

31. WangJ.*,Dai P., Chen J. (2014): Polyethylene naphthalatesingle-polymer-composites produced by the undercooling melt filmstacking method. CompositesScience and Technology.91: 50-54.

32. WangJ.*,Mao Q., Chen J. (2013): Preparation of polypropylene single-polymercomposites by injection molding. Journalof Applied Polymer Science.130(3): 2176-2183.

33. WangJ.*,Mao Q. (2013): A novel process control methodology based on theP-V-T behavior of polymer for injection molding. Advancesin Polymer Technology.32(S1): E474-E485.

34. WangJ.*,Peng J., Yang W. (2011): Filling-to-packing switchover mode based oncavity temperature for injection molding. Polymer-PlasticsTechnology and Engineering.50(12): 1273-1280.

35. WangJ.,Xie P., Ding Y., Yang W.* (2010): On-linepressure-volume-temperature measurements of polypropylene using atesting mold to simulate the injection-molding process. Journalof Applied Polymer Science.118(1): 200-208.

36. WangJ.,Xie P., Ding Y., Yang W.* (2009): On-line testing equipment of P-V-Tproperties of polymers based on an injection molding machine.PolymerTesting.28(3): 228.

代表性专利：

1. 王建、梁育璨、何鉴峰、任峰.基于材料特性的塑化螺杆智能设计系统及方法,202411551535.8, 发明

2. 王建.连续纤维增强热塑性聚合物复合材料管成型设备和方法,202210614864.7, 发明

3. 王建.单聚合物复合材料管,202210592763.4, 发明

4. 王建.双组份单聚合物复合材料制品热压成型方法及装置,202111534503.3, 发明

5. 王建.单聚合物复合材料制品过冷膜过热丝成型方法及装置.202111207513.6, 发明

6. 王建.一种摩擦感度测试装置及方法.202010705274.6, 发明

7. 王建.转矩流变测试用直角型模具.201510917518.6, 发明

8. 王建.补充容积式等容置换锁模装置.201410838369.X, 发明

9. 王建.一种等容置换内循环直压式锁模装置.201410838367.0, 发明

10. 王建.一种二板机锁模油缸结构.201310670709.8, 发明

11. 王建.补充容积式等容置换内循环锁模装置.201310670042.1, 发明

12. 王建.移模锁模一体式合模油缸结构.201310666955.6, 发明

13. 王建,陈晋南,彭炯.单聚合物复合材料制品熔融包覆辊压成型方法及设备.201310279402.5, 发明

14. 王建,陈晋南,彭炯.一种测定敏感性药料流变性能的方法.201210384181.3, 发明

15. 王建,陈晋南,毛倩超,彭炯.一种单聚合物复合材料制品注塑成型方法及设备.201210037657.6, 发明

奖励与荣誉：

1. 王建(2/10);精密塑料制品注射成型关键技术及装备的开发与应用,北京市科学技术委员会,科技进步,省部二等奖,2021

2. 王建(1/1);德国IKV塑料加工研究院优秀贡献奖,德国塑料加工研究院（IKV）,其他,国际学术奖,2020

3. 王建(1/1);德国洪堡资深学者,德国洪堡基金会,其他,国际学术奖,2020

4. 王建(1/1);德国RWTHAachen SFB国际合作中心优秀论文二等奖,其他,国际学术奖,2019

5. 王建(15/15);塑料精密成型技术与装备的研发及产业化,国家科技进步二等奖,国家二等奖,2011

6. 王建(10/10);高分子材料PVT性能在线测试技术及应用,中国石油化工协会技术发明二等奖,省部二等奖,2010

7. 王建;全国三好学生,国家,2007

8. 王建;北京地区高等学校优秀毕业生,2005