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程旺军
2024-04-24 12:21  










程旺军,中共党员,甘肃静宁人,工学博士,副教授,硕士研究生导师

研究方向(1)储氢设备结构设计与成形制造;(2)航空航天构件高性能加工与焊接;(3)超低温极限制造与性能评估;(4)农牧产品冷/解冻工艺与装置研发等。

n 个人及工作简历

2022.12-至今,新疆大学,机械工程学院,副教授硕导

2021.11-至今,新疆大学,机械工程专业,在读博士后;

2017.03-2021.10 哈尔滨工业大学,材料加工工程,工学博士;

2015.07-2017.02 中国重型机械研究院股份公司(原西安重型机械研究所),助工;

2012.09-2015.06 太原理工大学,材料加工工程,工学硕士;

2010.09-2012.07 太原理工大学,工程管理 (双学士学位),管理学学士;

2008.09-2012.07 太原理工大学,材料成型及控制工程,工学学士

n 科研项目

[1] 主持国家自然科学基金地区项目2024.01-2027.12,在研;

[2] 主持中国博士后科学基金面上项目2022.12-2024.12,在研;

[3] 主持新疆维吾尔自治区天池英才青年人才项目,2022.12-2025.12,在研;

[4] 主持新疆维吾尔自治区自然科学基金青年项目,2022.12-2025.12,在研;

[5] 主持新疆维吾尔自治区优秀博士后项目2023.06-2025.06,在研;

[6] 主持新疆维吾尔自治区高校基本科研业务费项目,2024.01-2026.12,在研;

[7] 主持太原理工大学横向1项,2022-2025,在研;

[8] 主持哈尔滨工业大学横向1项,2022-2024,在研;

[9] 参与丝绸之路经济带创新驱动发展试验区、乌昌石国家自主创新示范区科技发展计划项目,2023-2024,在研,骨干;

[10] 参与国家重点研发计划变革性技术关键科学问题重点专项,2020-2025.

n 学术及科研成果、专利、论文

(1) 学术论文

[1] Cheng Wangjun*, Cui Dongdong, Sun Yaoning. Cryogenic work-hardening behavior for a metastable austenitic stainless steel at liquid nitrogen temperature [J], Materials Science and Engineering: A, 2022, 816:144–352. (SCI, 一区,If=6.044)

[2] Cheng Wangjun, Liu Wei*, Yuan Shijian. Deformation behavior of Al-Cu-Mn alloy sheets under biaxial stress at cryogenic temperatures [J], Materials Science and Engineering: A, 2019, 759:357–367. (SCI, 一区,If=6.044)

[3] Cheng Wangjun, Liu Wei*, Fan Xiaobo, Yuan Shijian. Cooperative enhancements in ductility and strain hardening of a solution-treated Al-Cu-Mn alloy at cryogenic temperatures [J], Materials Science and Engineering: A, 2020, 790: 139707. (SCI, 一区, If=6.044)

[4] Cheng Wangjun, Chi Chengzhong*, Wang Yongzhen, Lin Peng, et al. 3D FEM simulation of flow velocity field for a 5052 aluminum alloy multi-row sprocket in cold semi-precision forging process[J]. Transactions of Nonferrous Metals Society of China, 2015, 25: 926-935. (SCI, 二区, If=3.752)

[5] Cheng Wangjun*, Gao Qiang, Sun Yaoning., et al. Research progress of freezing processes and devices for fresh meat products[J]. International Journal of Refrigeration, 2024, xx: xxx-xxx. (SCI, 二区, If=3.9, Accept)

[6] Yuan Shijian*, Cheng Wangjun, Liu Wei. Cryogenic formability of a solution-treated aluminum alloy sheet at low temperatures[J]. Journal of Material Processing Technology, 2021, 298: 117295. (SCI, 一区, If=6.162)

[7] Yuan Shijian*, Cheng Wangjun, Liu Wei, Xu Yongchao. A novel deep drawing process for aluminum alloy sheets at cryogenic temperatures [J]. Journal of Material Processing Technology, 2020, 284:116743. (SCI, 一区, If=6.162)

[8] Liu Wei*, Cheng Wangjun, Yuan Shijian. Analyses on formability and flow stress of an Al-Cu-Mn alloy sheet under biaxial stress at cryogenic temperatures [J], International Journal of Mechanical Sciences, 2021, 195: 106266. (SCI, 一区, If=6.772)

[9] Liu Wei*, Cheng Wangjun, Yuan Shijian, Xu Yongchao. Enhancing formability of AA2219 aluminum alloy friction stir welded blanks with preheating treatment [J]. Journal of Materials Engineering and Performance, 2018, 27:4819-4828. (SCI, 三区, If=2.036)

[10] Cheng Wangjun, Chi Chengzhong*, Wang Yongzhen, Lin Peng, et al. Volume calculation of the spur gear billet for cold precision forging with average circle method[J]. International Journal of Coal Science & Technology, 2014, 1(4): 456-462. (EI, 矿业工程, T1)

[11] Cheng Wangjun*, Chi Chengzhong, Wang Yongzhen, Lin Peng, et al. Upper-bound and finite element analyses of a multi-row sprocket during cold semi-precision forging process[J]. International Journal of Coal Science & Technology. 2015, 2(3): 245-253. (EI, 矿业工程, T1)

[12] Xv Yifei, Sun Yaoning, Cheng Wangjun, Zhang Yuhang. Engineering Process Optimization and Quality Stability Control of High-Speed Laser Cladding Coatings Based on AHP-FCE. Coatings. 2023;13(10).(SCI, 三区, If=3.4)

[13] Zhang Shilin, Sun Yaoning , Cheng Wangjun , Chen Yufeng , Gu Jin, Chen Gang. Microstructure and tribological behavior of CoCrFeNiMo0.2/SiC high-entropy alloy gradient composite coating prepared by laser cladding', Surface and Coatings Technology, 467: 129681.(SCI, 三区, If=5.4)

[14] Meng Acong, Sun Yaoning, Cheng Wangjun, Zhai Zhenguo, Chong Zhensun, Jiang Liheng. Hydrogen production performance of an Al-Ga-In-Sn quaternary alloy. Materials Today Sustainability, 2023, 21:100284.(SCI, , If=7.8)

[15] Zhang YuhangXu YifeiSun Yaoning, Cheng Wangjun. Surface quality optimization of laser cladding based on surface response and genetic neural network model. Surface Topography-Metrology and Properties, 2022, 10(4).(SCI, , If=2.7)

[16] Ma, Xufeng, Sun Yaoning, Cheng Wangjun, Chong Zhenzeng, Huang Liufei, Meng Acong, Jiang Liheng. 2022. Effect of high-speed laser cladding on microstructure and corrosion resistance of CoCrFeNiMo high-entropy alloy, Journal of Central South University, 29: 3436-46.(SCI, , If=2.4)

[17] Meng, Acong, Sun Yaoning, Cheng Wangjun, Zhai Zhenguo, Jiang Liheng, Chong Zhenzeng, Chen Yufeng, Wu Anqi. 2022. 'Mechanism of hydrogen generation from low melting point elements (Ga, In, Sn) on aluminum alloy hydrolysis, International Journal of Hydrogen Energy, 47: 39364-75. (SCI, , If=7.2)

[18] Chong ZhenzengSun YaoningCheng WangjunHan, Chenyang Ma XufengMeng, AcongJiang Liheng. 2023. 'Trace boronizing strengthened AlCoCrFeNi high-entropy alloy coating manufactured by laser remelting: Enhanced wear and corrosion resistances, Materials Letters, 330.(SCI, , If=3.0)

[19] Chong, Zhenzeng, Sun Yaoning , Cheng Wangjun, Han Chenyang,  Huang Liufei, Su Caijin,and Jiang Liheng. "Enhanced Wear and Corrosion Resistances of Alcocrfeni High-Entropy Alloy Coatings Via High-Speed Laser Cladding." Materials Today Communications, 2022, 33: 104417. (SCI, , If=3.8)

[20] Chong Zhenzeng, Sun Yaoning, Cheng Wangjun, Huang Liufei, Han Chenyang, Ma Xufeng, Meng Acong. "Laser Remelting Induces Grain Refinement and Properties Enhancement in High-Speed Laser Cladding Alcocrfeni High-Entropy Alloy Coatings. Intermetallics, 2022, 150: 107686. (SCI, , If=4.4)

[21] 刘伟*, 程旺军, 郝永刚, 苑世剑. 铝合金超低温变形行为与成形新原理[J]. 中国有色金属学报, 202232(07): 1845-1854.EI, 材料工程)

[22] 程旺军, 刘伟*, 胡蓝, 张志超, 徐永超. 2219铝合金拼焊板硬化方程的建立与液压成形过程分析[J].塑性工程学报, 2020, 27(10): 27-32. (中文核心, 机械工程T2)

[23] 程旺军, 池成忠*, 王永祯, 林鹏等. 坯料形状对多排链轮半精锻成形过程影响的数值模拟[J]. 锻压技术, 2015, 40(1): 130-136. (中文核心, 机械工程T2)

[24] 梁建平, 程旺军*. 基于数值模拟的锥形螺母冷镦挤成形分析及其模具设计[J]. 锻压技术, 2015, 40(7): 151-155. (通讯, 机械工程 T2)

[25] 程旺军,曾月,孙耀宁等. 降低冲模零件材料成本的方法研究[J].模具工业,2023,49(11):25-29.

[26] 程旺军, 张恒源刘伟等. 6061铝合金薄壁管-法兰组合接头超低温局部胀-压连接规律[J].锻压技术,2023,48(05):25-30+110.(通讯, 机械工程 T2)

[27] 种振曾,孙耀宁,程旺军. 纳米WCAlCoCrFeNi高熵合金涂层耐磨与耐蚀性能的影响[J].材料导报, 2022, 36(14): 56-61.EI, 材料工程)

[28] 程旺军,崔栋栋,孙耀宁,曾月. 基于液氢储运的超低温不锈钢微观组织演变与力学性能研究进展[J].太阳能学, 2024, xx(xx): xx-xx.EI, Accept

(1) 授权/申请发明专利

[1] 程旺军, 左水利, 师波, . 一种轴向热拉伸柔性复合塑料高压输送管试验装置. 2018.11.27 (发明专利,授权No. CN 106053228B)

[2] 程旺军,陈玉锋,孙耀宁, . 一种奥氏体不锈钢板表面超低温滚动压印强化方法与装置. 2022.04 (发明专利,受理 No. ZL20221033875.X)

[3] 程旺军,王鹏博,孙耀宁, . 一种双金属复合管超低温下界面结合强度测试方法与装置. 2022.04 (发明专利,受理 No. ZL202210428064.6)

[4] 程旺军,姜立恒,孙耀宁, . 一种铝合金薄壁锥形管与薄板超低温塑性连接方法及装置. 2022.03 (发明专利,受理 No. ZL202210324511.3)

[5] 程旺军,马子煜,高强,等. 一种不锈钢包铝质双金属环件径向局部热压塑性连接方法与装置. 2022.12 (发明专利,受理 No. ZL202211587938.9)

[6] 孙耀宁,程旺军,孟阿聪, . 一种铝合金薄壁管与薄壁法兰超低温塑性连接方法与装置. 2022.03 (发明专利,受理 No. ZL202110396560.3)

[7] 孙耀宁,孟阿聪, 程旺军,等. 一种用于制造可溶压裂球的铝合金及其制备方法. 2021.12 (发明专利,受理 No. CN 202111507886.5)

[8] 刘伟,程旺军, 苑世剑, 等. 一种铝合金超薄深腔曲面件超低温变形调控方法及装置. 2021.07 (发明专利,受理 No. CN CN115193995A)

[9] 刘伟,苑世剑,程旺军, . 一种大尺寸薄壁曲面件超低温成形装置及成型方法. 2021.05 (发明专利,受理 No. CN 112845787A)

[10] 孙耀宁,孟阿聪,程旺军 2023.3 一种水平井分段压裂中的封堵工具 (实用新型专利,授权:ZL 2023 2 0347843.3

[11] 程旺军,孙绍凯,任智硕,成龙坡,张驰涵 2023.5 冷冻台(外观专利,授权:2023 3 0259027.2

n 联系方式

邮箱:chengwangjun2008@126.com(优先)或chengwangjun@xju.edu.cn

地址:新疆乌鲁木齐市水磨沟区华瑞街777号新疆大学博达校区

邮编:830017

课题组学术氛围好、出成果快,欢迎机械制造、材料加工以及工程力学等专业的研究生报考!



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