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学位:工学博士
毕业院校:南京航空航天大学
电子邮箱:Zengronghu@126.com
办公地址:交通大楼202
联系电话:15862517022
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988 访问 |
胡增荣
工学博士
副教授;硕士生导师
huzengrong@suda.edu.cn
15862517022
苏州市相城区济学路8号 轨道交通学院邮编:215137
主要研究方向
1. 金属增材制造理论及工艺
2. 运载工具轻量化技术
3. 石墨烯增强金属基复合材料
学习和工作经历
2011.09-2017.04南京航空航天大学机电学院航空宇航制造工程系博士
2012.02-至今苏州大学轨道交通学院车辆工程系副教授/硕导
社会兼职
JMPT、Journal of Alloys and Compounds、Composites Part B等期刊审稿人
承担项目
承担国家、省部、市级及企业横向项目10余项。
主要成果
苏州大学优秀毕业论文指导教师
苏州大学优秀实习指导教师
2018江苏省双创科技副总
在JMPT、Journal of Alloys and Compounds、Nanotechnology、Composites Part B等国内外期刊发表教学科研论文100余篇,部分论文如下:
1. Zengrong Hu ZS, Feng Chen, Jiale Xu, Changjun Chen. Wear and Friction Property of Laser Sintered Graphene Nickel Composite Coating.
2. Zengrong Hu YL, Xueliang Fan, Feng Chen, Jiale Xu. Mechanical and Tribological Property of Single Layer Graphene Oxide Reinforced Titanium Matrix Composite Coating. Advances in Materials. 1995;02014-1-02014-6.
3. Hu Z, Tong GQ. Laser sintered thin layer graphene and cubic boron nitride reinforced nickel matrix nanocomposites2015. 967302 p.
4. Hu Z, Tong GQ, Lin D, Nian Q, Shao J, Hu Y, et al. Laser Sintered Graphene Nickel Nanocomposites. Journal of Materials Processing Technology. 2015;231.
5. Hu Z, Tong GQ, Zhang C, Guo H, Xu J, Chen c. Corrosion resistance and hardness of laser sintered graphene-copper nanocomposites. 2015;27.
6. Hu Z, Saei M, Tong GQ, Lin D, Nian Q, Hu Y, et al. Numerical Simulation of temperature field distribution for laser sintering graphene reinforced nickel matrix nanocomposites. Journal of Alloys and Compounds. 2016;688.
7. Hu Z, Tong GQ, Lin D, Chen c, Guo H, Xu J, et al. Graphene-reinforced metal matrix nanocomposites - A review. Materials Science and Technology. 2016;32.
8. Hu Z, Tong GQ, Lin D, Nian Q, Shao J, Hu Y, et al. Corrigendum to “Laser sintered graphene nickel nanocomposites” [J. Mater. Process. Technol. 231 (2016) 143–150]. Journal of Materials Processing Technology. 2016;235:105.
9. Hu Z, Tong GQ, Nian Q, Xu R, Saei M, Chen F, et al. Laser sintered Single Layer Graphene Oxide Reinforced Titanium Matrix Nanocomposites. Composites Part B: Engineering. 2016;93.
10. Hu Z, Tong GQ, Xu R, Zhao L, Chen c, Zhang M, et al. Laser Sintered Graphene Reinforced Titanium Matrix Nanocomposites2016.
11. Hu Z, Tong GQ, Zhang C, Chen c, Zhang M, Guo HF, et al. Corrosion resistance and hardness of laser sintered graphene reinforced nickel matrix nanocomposites. Cailiao Rechuli Xuebao/Transactions of Materials and Heat Treatment. 2016;37:56-60.
12. Zhou J, Xu J, Huang S, Hu Z, Meng XK, Feng X. Effect of laser surface melting with alternating magnetic field on wear and corrosion resistance of magnesium alloy. Surface and Coatings Technology. 2016;309.
13. Chen C, Yan K, Qin L, Zhang M, Wang X, Zou T, Hu, Z. Effect of Heat Treatment on Microstructure and Mechanical Properties of Laser Additively Manufactured AISI H13 Tool Steel. Journal of Materials Engineering and Performance. 2017;26(11):5577-89.
14. Hu Z, Chen F, Lin D, Nian Q, Parandoush P, Zhu X, et al. Laser additive manufacturing bulk graphene–copper nanocomposites. Nanotechnology. 2017;28(44).
15. Ren B, Zhang M, Chen C, Wang X, Zou T, Hu Z. Effect of Heat Treatment on Microstructure and Mechanical Properties of Stellite 12 Fabricated by Laser Additive Manufacturing. Journal of Materials Engineering and Performance. 2017;26(11):5404-13.
16. Zhou J, Xu J, Huang S, Hu Z, Meng X, Fan Y. Microstructure and mechanical properties of Cr12MoV by ultrasonic vibration-assisted laser surface melting. Materials Science and Technology. 2017;33(10):1200-7.
17. 胡增荣, 童国权, 陈长军, 张敏, 郑祖山, 徐家乐, 郭华锋, 王晓南. 激光熔敷镍石墨烯立方氮化硼涂层的耐磨性能. HIGH POEWER LASER AND PARTICLE BEAMS. 2017;Vol. 29, No. 2.
18. Hu Z, Chen F, Xu J, Ma Z, Guo H, Chen C, et al. Fabricating graphene-titanium composites by laser sintering PVA bonding graphene titanium coating: Microstructure and mechanical properties. Composites Part B: Engineering. 2018;134:133-40.
19. Hu Z, Chen F, Xu J, Nian Q, Lin D, Chen C, et al. 3D printing graphene-aluminum nanocomposites. Journal of Alloys and Compounds. 2018;746:269-76.
20. Hu Z, Li Y, Zhan Y, Huan P, Wang X, Chen C. Fabricating SiC Nanowire by Vacuum Heating Multilayer Graphene in Silicate Refractory Tube. IOP Conference Series: Materials Science and Engineering. 2018;381.
21. Hu Z, Wang X, Fan X, Chen C, Wu D. Vacuum heat treated multilayer graphene. 2018.
22. Zengrong HU XF, Shaoxiong Guo. Tribological Performance of Graphene-Copper-Iron Composite Coating. Advances in Engineering Research. 2018;146.
23. Zhan Y, Yao K, Hu Z, Zeng Q. Refractive index sensor based on total scattering of plasmonic nanotube2018. 108 p.
24. 陈夏明, 王晓南, 颜倩, 王高松, 胡增荣, 张敏, 陈长军. 镍箔对DP980_A6061异种激光焊接接头组织性能的影响. 中国激光. 2018;Vol.45, No.11 November, 2018.
25. Hu Z, Wang D, Chen C, Wang X, Chen X, Nian Q. Bulk titanium–graphene nanocomposites fabricated by selective laser melting. Journal of Materials Research. 2019;34(10):1744-53.
26. Huan P-C, Wang X-N, Yang L, Zheng Z, Hu Z, Zhang M, et al. Effect of Martensite Content on Failure Behavior of Laser Welded Dual-Phase Steel Joints During Deformation. Journal of Materials Engineering and Performance. 2019;28.
27. Huan P-C, Wang X-N, Yang L, Zheng Z, Hu Z-R, Zhang M, et al. Effect of Martensite Content on Failure Behavior of Laser Welded Dual-Phase Steel Joints During Deformation. Journal of Materials Engineering and Performance. 2019;28(3):1801-9.
28. Pengcheng H, Wang X, Tiancai Z, Wengang C, Hu Z, Zhang M, et al. Microstructure and Mechanical Properties of Laser Welded Joint of 800 MPa Grade Hot-Rolled High Strength Steel. Chinese Journal of Lasers. 2019;46:0102002.
29. 环鹏程, 王晓南, 朱天才, 陈文刚, 胡增荣, 张敏, 陈长军. 800MPa级热轧高强钢激光焊接接头的组织和力学性能. 中国激光. 2019;Vol. 46, NO. 1.
30. Chen X, Wang X, Liu Z, Hu Z, Huan P, Yan Q, et al. Effect of Cu content on microstructure transformation and mechanical properties of Fe-Al dissimilar laser welded joints. Optics & Laser Technology. 2020;126.
31. Chen X, Wang X, Sun Q, Hu Z, Huan P, Yi G, et al. Improving the mechanical properties of PHS laser welded joints by adding Ni foil to suppress δ-ferrite. Journal of Materials Research and Technology. 2020;9(3):5184-93.
32. Chen X-M, Dong Q-P, Liu Z-G, Wang X-N, Zhang Q-Y, Hu Z-R, et al. Fe-bearing intermetallics transformation and its influence on the corrosion resistance of Al–Mg–Si alloy weld joints. Journal of Materials Research and Technology. 2020;9(6):16116-25.
33. Dai R, Wang M, Wang D, Hu Z, Green MD, Nian Q. Understanding mechanical behavior of metallic foam with hollow struts using the hollow pentagonal dodecahedron model. Scripta Materialia. 2020;182:114-9.
34. Huan P-C, Wang X-N, Zhang J, Hu Z-R, Chen W-G, Nagaumi H, et al. Effect of wire composition on microstructure and properties of 6063 aluminium alloy hybrid synchronous pulse CMT welded joints. Materials Science and Engineering: A. 2020;790.
35. Wang X, Zhang Z, Hu Z, Sun Q, Di H, Lv F, et al. Effect of Ni foil thickness on the microstructure of fusion zone during PHS laser welding. Optics & Laser Technology. 2020;125.
36. Zhao L, Hu Z,* Wang X, Chen X, Huan P, Zhang H. Laser Surface Remelting of AISI 4140 Steel. IOP Conference Series: Materials Science and Engineering. 2020;774(1).
37. Dai R, Guo Y, Hu Z, Wang QH, Nian Q. Three-dimensional hollow graphene–metallic nanocomposite foam manufactured by polymer-templated electrochemical co-deposition. Journal of Materials Research. 2021;36(17):3539-47.
38. Hu Z-r, Dai R, Wang D-n, Wang X-n, Chen F, Fan X-l, et al. Preparation of graphene/copper nanocomposites by ball milling followed by pressureless vacuum sintering. New Carbon Materials. 2021;36(2):420-8.
39. Yan F, Hu Z, Wang X, Chen X, Huan P, Li W, et al. Study on microstructure and thermal conductivity of semi-solid die casting aluminum alloy. E3S Web of Conferences. 2021;268.
40. Chen X, Wang X, Huan P, Hu Z, Wu Z, Zhang B, et al. Effect of Cold Metal Transfer Mix Synchro-Pulse Process on the Overall Morphology, Microstructure and Mechanical Properties of Wire+Arc Additively Manufactured AA2219 Alloy. Metals and Materials International. 2022;29(2):552-63.
41. Wang X, Xie Y, Liu Z, Sun Q, Shen X, Zhang Q, Hu Z. Zn-induced liquid metal embrittlement and mechanical properties of advanced high-strength steel with resistance spot weld. Materials Science and Engineering: A. 2022;843.
42. Xu J, Hu Z, Wang S, Tan W, Zhou J. Laser cladding Co-based coating coupled with electromagnetic/ultrasonic compound energy field. Materials Science and Technology. 2022;39:1-12.
43. Hu Z, Wu Z, Luo S, Wang X, Nian Q, Chen Y, et al. Large scale production of graphene aluminum composites by stir casting: Process, microstructure and properties. Journal of Materials Research and Technology. 2023;27:681-91.
44. Li Z-x, Wang X-n, Chen J, Zhang Z-y, Hu Z-r, Chu Y-j, et al. Influence of laser surface treatment on the microstructure distribution, bearing capacity and impact property of 1.0C‐1.5Cr steel. Materials Today Communications. 2023;35.
45. Wu Z, Luo S, Wang D, Wang X, Chen X, Nagaumi H, Hu Z.* Effect of thermophysical properties on porosity and microstructure of laser welded cast and wrought aluminum alloy dissimilar lap joints. Journal of Materials Research and Technology. 2023;26:1833-49.
46. Luo S, Wu Z, Wang D, Zhang J, Hu Z, Wang X, et al. Solidification microstructures and softening behavior of laser welded 6082-A356 aluminum alloy dissimilar butt joints. Materials Today Communications. 2024;38:108411.
47 Li Z X, Wang X N, Shen X J, Hu Z,et al. Achieving balance between surface strengthening and ductility in the laser surface treatment of high-carbon steel via heterostructure[J]. Materials Science & Engineering A, 2025, 924: 147777.
48 Cao M, Luo S C, Jiang X W,Hu Z,* et al. Wire arc additive manufacturing of a novel Al-Si-Mg-Cu-Zn alloy via in-situ laser remelting[J]. Materials Science & Engineering A, 2025, 930: 148165.
49 Jiang X W, Luo S C, Cao M, Hu Z,* et al. Property enhancement in 6D10 aluminum alloy welds: A comparative study of CMT+P and oscillating laser welding techniques with novel Al-Si-Cu-Mg-Zn filler wire[J]. Journal of Materials Processing Technology, 2025, 339: 118830.
50 Zhu Q L, Yu J M, Xu C,Hu Z,* et al. Advancing near-infrared and blue hybrid laser welding: Energy efficiency, microstructure and mechanical properties of dissimilar Al-Mg-Si alloy joints[J]. Journal of Materials Processing Technology, 2025, 340: 118842.
51 Jiang, X., Luo, S., Chen, M., Nagaumi, H., Wu, Y., Cao, M., Wang, X., & Hu, Z. *(2025). In-situ precipitation kinetics and property gradients of a novel Al-Si-Cu-Mg alloy fabricated via CMT wire-arc additive manufacturing. Journal of Alloys and Compounds, 1040, 183430. https://doi.org/10.1016/j.jallcom.2025.183430
52 Tao, Y., Luo, S., Zhang, J., Wang, X., Chen, X., Hu, Z., & Nagaumi, H. (2024). Effect of aging state on microstructure and properties of heat affected zone in Al-Mg-Si-Cu alloy welded joints. Journal of Materials Research and Technology, 33, 3045–3057. https://doi.org/10.1016/j.jmrt.2024.10.022
53 Mu, H., Luo, S., Wang, L., Li, Z., Chen, M., Wang, X., Nagaumi, H., & Hu, Z.* (2024). Microstructure and mechanical properties of aluminum alloy laser welded joint assisted by alternating magnetic field. Journal of Materials Research and Technology, 33, 6842–6852. https://doi.org/10.1016/j.jmrt.2024.11.054
54 Luo, S., Tao, Y., Wu, Z., Wang, X., Hu, Z., & Nagaumi, H. (2025). Effect of pre-aging and paint baking processes on precipitation behavior in heat-affected zone of CMT welded Al-Mg-Si-Cu alloy joint. Journal of Materials Research and Technology, 35, 6156–6166. https://doi.org/10.1016/j.jmrt.2025.02.236
55 Xinpei Liu, Honglin Mou, Zengrong Hu.* Study on Microstructure and Properties of LZ50 Axle Steel Repaired by Laser Additive Remanufacturing[J]. AMMEE Transactions on Engineering and Technology Research, 2024, Volume 2: 176–180.
56 Zengrong Hu, Honglin Mu, Shuncun Luo, et al. Effect of Swinging Laser on Porosity, Microstructure and Mechanical Properties of Laser Welded Aluminum Alloy Joints with Different Lap Forms[J]. Optics and Lasers in Engineering, 2024, 183: 108541. https://doi.org/10.1016/j.optlaseng.2024.108541
57 Mingrui Chen, Shuncun Luo, Xiaming Chen, Zengrong Hu* et al. Effect of Deposition Parameters and Deposition Height on the Microstructure and Properties of Laser–Cold Metal Transfer Composite Additively Manufactured 2319 Aluminum Alloy[J]. Materials, 2024, 17(12): 2914. https://doi.org/10.3390/ma17122914
58 Zengrong Hu, Mingrui Chen, Zhikang Wu, et al. Effect of Interlayer Cooling on Microstructure and Microhardness of FeCoNiCrAl High-Entropy Alloy Fabricated by Laser Additive Manufacturing[J]. Journal of Materials Engineering and Performance, 2025, 34(17): 18426–18433. https://doi.org/10.1007/s11665-025-10678-9
论文详细情况:https://www.researchgate.net/profile/Zengrong_Hu
申请实用新型和发明专利多项,部分授权发明及实用新型专利如下:
[2]苏州大学.一种磁场辅助辊压激光焊接装置: 202510858725.2[P].2025-08-29.
[3]苏州大学.一种高铁含量的铝合金焊丝及其制备方法与应用: 202511033672.7[P].2025-08-26.
[5]苏州大学.一种提高6XXX系铝合金焊缝强度和耐蚀性能的方法: 202510687981.X[P].2025-08-08.
[6]苏州大学.一种提高铝合金焊缝强度、韧性和抗疲劳性能的方法: 202510688039.5[P].2025-08-08.
[8]苏州大学.一种用于6XXX系铝合金的填充材料及其焊接工艺: 202510688006.0[P].2025-08-01.
[9]苏州大学.一种铝合金焊接材料及高强韧焊缝制备方法: 202510687959.5[P].2025-07-25.
[10]苏州大学.一种提高6XXX系铝合金焊缝强度和耐蚀性能的方法: 202510687981.X[P].2025-06-27.
[11]苏州大学.一种铝合金焊接材料及高强韧焊缝制备方法: 202510687959.5[P].2025-06-27.
[12]苏州大学.一种用于6XXX系铝合金的填充材料及其焊接工艺: 202510688006.0[P].2025-06-27.
[13]苏州大学.一种提高铝合金焊缝强度、韧性和抗疲劳性能的方法: 202510688039.5[P].2025-06-24.
[14]苏州大学.一种添加箔材金属层的可调对接焊夹具: 202421705471.8[P].2025-06-10.
[15]苏州大学,魏桥(苏州)轻量化研究院有限公司.一种6XXX系高强铝合金焊接填充材料的成分设计方法: 202311873129.9[P].2025-03-18.
[16]山东宏桥新型材料有限公司,苏州大学,山东宏奥汽车轻量化科技有限公司,等.一种Al-Mg-Si-Cu系铝合金的复合焊接方法: 202311496279.2[P].2025-02-11.
[17]苏州大学.一种双激光束协同制备焊缝多级异质结构的方法及装置: 202410223447.9[P].2025-01-10.
[18]苏州大学.一种高能束流辅助重熔电弧增材的方法及装置: 202411457954.5[P].2025-01-07.
[19]苏州大学.一种激光—电弧复合焊接对接夹具: 202421150069.8[P].2025-01-07.
[20]苏州大学.一种异种金属搭接装置及其使用方法: 202410961927.5[P].2024-12-03.
[21]苏州大学.一种新型计算机主机箱: 202420361668.8[P].2024-09-27.
[23]苏州大学.一种电加热式防冻汽车隐藏门把手: 202323583369.3[P].2024-07-19.
[28]苏州大学.一种双激光束协同制备焊缝多级异质结构的方法及装置: 202410223447.9[P].2024-05-03.
[29]山东宏桥新型材料有限公司,苏州大学,山东宏奥汽车轻量化科技有限公司,等.一种Al-Mg-Si-Cu系铝合金的复合焊接方法: 202311496279.2[P].2024-04-30.
[30]苏州大学,魏桥(苏州)轻量化研究院有限公司.一种6XXX系高强铝合金焊接填充材料的成分设计方法: 202311873129.9[P].2024-04-05.
[31]苏州大学.一种复合能场协同制备异种金属复合板带的装置及方法: 202311529279.8[P].2024-03-12.
[32]苏州大学.一种改善可热处理强化铝合金焊接接头热影响区软化的方法: 202311464046.4[P].2024-03-08.
[35]苏州大学.一种激光及脉冲电流协同制备异种金属板带的装置及方法: 202311591813.8[P].2024-02-20.
[36]苏州大学.一种适用于钢-铝薄板激光搭接焊接的新型工艺及方法: 202311703390.4[P].2024-01-30.
[37]魏桥(苏州)轻量化研究院有限公司,苏州大学.电脉冲处理提高焊接质量的方法: 202311712190.5[P].2024-01-26.
[41]苏州大学.一种高度可调电脑显示器: 202321292878.8[P].2023-12-19.
[42]苏州大学,魏桥(苏州)轻量化研究院有限公司.脉冲激光冲击-增材复合制造超细共晶高熵合金方法及装置: 202310784260.1[P].2023-08-15.
[44]苏州大学.一种软体气动机器人手爪: 202221688105.7[P].2023-06-23.
[46]常州信息职业技术学院.一种抗磨减摩高熵合金涂层的制备方法: 202111323456.8[P].2023-05-16.
[48]苏州大学.一种混凝土预制件微波固化装置: 202222812577.5[P].2023-05-02.
[49]苏州金澄精密铸造有限公司.一种静电喷漆装置: 202222958930.0[P].2023-04-25.
[50]苏州大学.一种激光焊接机: 202222739222.8[P].2023-04-18.
[51]苏州大学.一种激光增材制造金属蜂窝芯的装置: 202222054919.1[P].2023-04-11.
[52]苏州大学.一种轨道交通用通风设备: 202222738725.3[P].2023-04-11.
[58]苏州大学.一种机械加工用切割装置: 202222763099.3[P].2023-03-24.
[59]苏州大学.一种电缆线束紧机构: 202222699568.X[P].2023-03-24.
[60]苏州大学.一种机械加工用抛光设备: 202222779965.8[P].2023-03-21.
[61]苏州大学.一种带反光条的防火电线: 202221494434.8[P].2023-03-21.
[62]苏州大学.一种列车车轴激光快速清洗装置: 202222812599.1[P].2023-03-14.
[63]苏州大学.一种便于接头连接的电缆: 202222763245.2[P].2023-03-14.
[65]苏州大学.一种轨道交通用指示牌: 202222703623.8[P].2023-02-21.
[66]苏州大学.一种水面自动清理船: 202222726640.3[P].2023-02-21.
[67]苏州大学.一种具有清洁机构的轨道交通通风装置: 202222779964.3[P].2023-02-17.
[68]苏州大学.自动无人清理船: 202222847455.X[P].2023-02-03.
[69]苏州金澄精密铸造有限公司.一种铝合金压铸件柔性去毛刺设备: 202211412159.5[P].2023-01-17.
[70]苏州大学.一种高安全性电缆: 202221494093.4[P].2023-01-06.
[71]苏州大学.一种电缆收集装置: 202221555201.4[P].2023-01-06.
[72]苏州大学.一种便携式电缆快速检测装置: 202221554728.5[P].2022-11-22.
[75]苏州大学.一种机械设备用电线: 202221687062.0[P].2022-09-27.
[78]常州信息职业技术学院.一种延长零件摩擦副表面使用寿命的方法和装置: 202110648274.1[P].2022-07-08.
[79]苏州大学.一种梯度材料制备装置: 202122696111.9[P].2022-06-17.
[80]南京航空航天大学.一种复合填充的空间点阵激光防护结构: 202220095305.5[P].2022-06-17.
[81]苏州大学.一种镀铝钢-铝合金的焊接方法: 202010302748.2[P].2022-06-10.
[82]南京航空航天大学.一种复合填充的空间点阵激光防护结构及其制备方法: 202210041722.6[P].2022-05-13.
[83]苏州大学.一种金属半固态浆料的制备装置: 202123116910.0[P].2022-05-10.
[84]苏州大学,山东宏桥新型材料有限公司.一种高强焊缝的制备方法: 202210059719.7[P].2022-04-08.
[85]苏州大学.一种改善焊缝强韧性的激光焊接方法: 202111655786.7[P].2022-03-22.
[86]苏州大学.一种金属半固态浆料的制备装置及制备方法: 202111504652.5[P].2022-02-18.
[87]苏州大学.一种具有预热及缓冷功效的薄板焊接装置: 202122335899.0[P].2022-02-18.
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硕士研究生招生专业:
1.车辆工程专业
2.载运工具运用工程方向(交通运输专硕)
专业背景要求:机械工程、车辆工程、冶金、材料科学等。
