师资队伍

赵明(副教授)

作者:审核:发布者:张秀良发布时间:2018-12-04浏览次数:11982

»姓名:赵明

»系属:材料加工工程系

»学位:工学博士

»职称:副教授

»专业:材料加工工程

»导师类别:硕导

»电子邮箱:zhaoming08@upc.edu.cn

»联系电话:15318790152WeChat

»通讯地址:山东省青岛市黄岛区长江西路66

»概况:赵明,副教授,硕导。中国机械工程学会会员,焊接学会计算机辅助焊接工程专业委员,《金属加工(热加工)》和《焊管》编辑委员会委员,《金属加工(热加工)》优秀编委。长期从事油气管线与海洋平台焊接、电弧增材制造、材料加工过程的数值模拟与智能控制等方面的研究。主持和参与国家级、省部级及横向科研项目十余项,发表论文四十余篇,授权专利4项。

 ◎研究方向

   1. 先进材料的连接

   2. 电弧增材制造

   3. 数值模拟与智能控制

 ◎教育经历

   2001.09-2006.12 山东大学,硕博连读  工学博士

   1992.09-1996.06 吉林大学,本科      工学学士

 ◎工作经历

   2018.08 - 至今   太阳成集团tyc41183,tyc41183太阳成集团,副教授

   2012.01-2013.01  美国俄亥俄州立大学,访问学者

   2009.12-2018.07  太阳成集团tyc41183,机电工程学院,副教授

   2007.01-2009.11  太阳成集团tyc41183,机电工程学院,讲师

   1996.07-2001.08  成都大中华焊接材料有限公司,助理工程师

 ◎学术兼职

   1. 中国机械工程学会会员

   2. 中国机械工程学会焊接学会计算机辅助焊接工程专业委员会委员

   3. 《金属加工(热加工)》编辑委员会委员

   4. 《焊管》编辑委员会委员

 ◎主讲课程

   1. 材料加工传输原理

   2. 高效焊接方法

   3. 先进材料的连接

   4. 机器人焊接

   5. 机械热加工实习

   6. 专业外语综合实践

   7. 国际教育课程

  1.  Advanced Welding and Joining Processes (32 Hours)

  2. Solid/Semi-Solid Materials Processing Technologies (32 Hours)

  3.  High Efficient Welding and Joining Processes (32 Hours)

  4. Heat and Mass Transfer in Materials Science and Engineering (16 Hours)

  5. Advanced Materials Processing (32 Hours)

  6. Robot Perception, Localization and Navigation (32 Hours)

 ◎指导研究生

已指导研究生20余人,其中1人获山东省优秀毕业生

 ◎承担科研项目

   1. 横向项目:隐身***材料加工与测试(2024.01-2024.12

   2. 横向项目:***双金属复合管自动焊接技术研究(2021.01-2021.12

   3. 山东省自然科学基金面上项目(ZR2020ME013

   4. 山东省自然科学基金面上项目(ZR2018MEE020

   5. 山东省自然科学基金面上项目(ZR2016EMM22

   6. 国家自然科学基金(51305461

   7. 教育部科学研究重大项目(313056

   8. 教育部自主创新科研计划项目(13CX02075A

   9. 教育部博士点基金(20110133110003

   10. 教育部自主创新科技专项(11CX05003A

   11. 山东省自然科学基金面上项目(ZR2011EMM015

   12. 山东省自然科学基金面上项目(ZR2011EL023

   13. 山东省自然科学基金面上项目(ZR2010EM073

   14. 青岛市科技计划基础研究项目(09-1-3-37-jch

   15. 国家自然科学基金(50806082

   16. 中国石油大学博士科研启动基金资助项目(Y070305

 ◎指导学生获奖情况

   1. 2025 范金峰 姚立爽 史宇洋 张晓豪  获第八届全国大学生焊接创新大赛一等奖

   2. 2024 牛福伟 董祥宇 潘云倩 杨学燕  获第七届全国大学生焊接创新大赛一等奖

   3. 2024 夏  涛  获校级优秀本科毕业论文

   4. 2024 乔梓珅  获校级优秀本科毕业论文

   5. 2022 陈洪元 王俊杰 崔朝鹏  获第五届全国大学生焊接创新大赛二等奖

   6. 2021 宋袁芳  获校级优秀本科毕业论文

   7. 2021 陈洪元 宋佳璐 陶斯宇  获省级大学生创新创业训练项目

   8. 2020 于牧冰 徐  锐 王佳丽  获国家级大学生创新创业训练项目

   9. 2019 吴桐  荣获山东省优秀毕业研究生

   10. 2018 宋锴星 陈蒙 王阳  获国家级大学生创新创业训练项目

   11. 2022 肖明贵  获院级优秀本科毕业论文

   12. 2014 毕敬获  获校级优秀本科毕业论文

   13. 2008 翟  磊  获校级优秀本科毕业论文

   14. 2007 秦亚伟  获校级优秀本科毕业论文

 ◎荣誉称号

   1. 2022-2024年度《金属加工(热加工)》优秀编委

   2. 2021-2022年度太阳成集团tyc41183优秀工会会员

   3. 2021-2022学年度太阳成集团tyc41183“十佳百优”班主任

   4. 2014-2015学年度中国石油大学(华东)“十佳百优”班主

   5. 2011-2012学年度太阳成集团tyc41183“十佳百优”班主

 ◎发表论文

 [1] Ming Zhao, Shuying Jiang, Chuansong Wu, Lishuang Yao, Tao Xia. Synergistic regulation of alternating magnetic field and torch tilt angle for high-precision fabrication of self-supporting inclined aluminium alloy components via CMT-WAAM[J]. Journal of Materials Research and Technology, 2026, 42: 729-743.

 [2] 赵明, 张晓豪, 范金峰, 史宇洋, 姚立爽, 武传松. 超常热加工过程中热传导理论的演化与应用:从傅里叶导热模型到非傅里叶导热模型[J]. 材料工程, 2025, 53(9): 39-49.

 [3] 汤世云, 赵明, 丁浩真, . LNG用奥氏体不锈钢NBG-GTAW接头微观组织与力学性能[J]. 焊接, 2025, (5): 44-53.

 [4] Jiang Shuying, Xu Hongming, Zhao Ming, Huang Wanqun. Effects of La content on microstructure and properties of Ni-Cr-Ti-La Laser-cladded and plasma-nitrided layers[J]. Transactions of The Indian Institute of Metals, 2025, 78: 162. https://doi.org/10.1007/s12666-025-03644-5

 [5] Jiang Shuying, Xu Hongming, Zhao Ming, Huang Wanqun. Effects of nitriding parameters on the microstructure and properties of laser-cladding and plasma-nitriding composite modified layers[J]. Bulletin of Materials Science, 2025, 48: 47. https://doi.org/10.1007/s12034-025-03404-7

 [6] Ming Zhao, Xiao Wang, Shaobiao Tang, Zhigang Lin, Hongyuan Chen. Determination and characterization of heat input, microstructure and performance in Cold Metal Transfer weld brazing of dissimilar AA6061 T6 to SS304 sheets[J]. Transactions of the Indian Institute of Metals, 2023, 76: 1 359–1 369.

 [7]蒋淑英, 张军利, 赵明. 基于高熵合金中间层的铜/TIG焊接头组织与性能. 中国石油大学学报(自然科学版), 2023, 47(6): 154-161.

 [8]蒋淑英, 蔡畅, 赵明, 黄万群. 基于高熵合金中间层的Q235/6061铝合金电阻点焊接头的组织与性能. 焊接学报, 2023, 44(7): 71-78.

 [9] Ming Zhao, Xuezhi Feng, Zhaopeng Cui, Junjie Wang, Hongyuan Chen. Influence of transverse auxiliary magnetic field on weld formation and joint quality in spiral submerged arc welding of X80 steel linepipe[J]. Welding in the World, 2022, 66(12): 2497–2508.

 [10]陈世伟, 汤世云, 赵明, 卫旭敏. 海上风电导管架重要节点的三次焊接返修工艺[J]. 焊接技术, 2022, 51(11): 62-67+114.

 [11]汤世云, 赵明, 韦生, 卫旭敏, 李振华. 海上风电导管架用钢管的JCOE加工制造与性能评定[J]. 焊接, 2022, (10): 59-64.

 [12]赵明, 李晴, 宋慧琴, 喻竹, 杨培庆, 郭圣龙, 耿会龙. 管线钢管焊接技术的研发现状与发展趋势[J]. 金属加工(热加工), 2022, (9): 21-25+58.

 [13] Ming Zhao; Junxu Chen; Mubing Yu; et al. Effect of transverse magnetic field on weld formation and microstructure & properties of high-speed hot-wire tungsten inert gas welding joints[J]. Science and Technology of Welding and Joining, 2020, 25(6): 521-528.

 [14]Shuying Jiang, Hongming Xu, Ming Zhao, Yongxing Sun. Microstructure and properties of Cr-Ni-Ti-RE cladded-nitrided composite modified layers on N80 steel. Surface and Coatings Technology, 2019, 361: 231-239.

 [15]Wenhao Wu, Ming Zhao, Haiyan Wang, et al. Twin-Wire Pulsed Tandem Gas Metal Arc Welding of API X80 Steel Linepipe[J]. The International Journal of Corrosion, 2018, DOI: 10.1155/2018/7284246.

 [16] Zhao Ming, Wu Tong, Wei Fei, et al. Temperature Field and Fluid Flow of Multi-wire Tandem Submerged Arc Welding of Longitudinal Spiral Weld Seam[C]. Proceedings of the WSE & CAWE, Jinan, 2017.10.18-20.

 [17] M. Zhao, F. Wei, W. Q. Huang, et al. Experimental and numerical investigation on combined girth welding of API X80 pipeline steel[J]. Science and Technology of Welding and Joining, 2015, 20(7): 622-630.

 [18]万夫伟; 郭新芳; 赵明; . S32205双相不锈钢GTAW焊接工艺研究[J].焊接技术, 2021, 50(10): 60-62.

 [19]封学志, 赵明, 曹梅青. Q235钢等离子熔覆FeZrB2-ZrC复合涂层的组织与性能研究[J]. 热加工工艺, 2019, 48(16): 106-110+115.

 [20]万夫伟, 郭新芳, 赵明, . 2A12铝合金搅拌摩擦焊温度场及接头组织分析[J]. 焊管, 2016, 39(9): 13-18.

 [21]赵明, 王海燕, 万夫伟, . X80级管线钢三丝埋弧焊接热过程的数值分析[J]. 焊接学报,2014, 35(10): 17-20.

 [22] Ming Zhao, Haiyan Wand, Fei Wei, Detong Luo. Numerical and experimental investigation into single-wire and multi-pass welding of super high-strength low-alloy pipeline steel[C]. Proceedings of 4thJapan-China Workshop on Welding Thermo-Physics, Osaka, Japan, 2014, 21-24.

 [23]李瑞英, 赵明, 吴春梅. 基于SYSWELD的双椭球热源模型参数的确定[J]. 焊接学报, 2014, 35(10): 93-96.

 [24]赵明, 罗德通, 王海燕. CO2气体保护焊接温度场与焊缝成形的有限元分析[J]. 机械工程学报, 2013, 49(14): 80-85.

 [25]赵明, 杜丹丹, 罗德通. 多参数对GTAW焊接温度场影响分析[J]. 焊接学报, 2013, 34(3): 21-24.

 [26] Zhao Ming, Zhang Xingyuan, Wan Fuwei. Effect of the distribution parameter of heat source on temperature profiles in GTAW[J]. China Welding, 2012, 21(4): 20-25.

 [27]李瑞英, 赵明, 周鸿雁. 基于SYSWELDGTAW三维动态熔池形状的有限元模拟[J]. 焊接学报, 2011, 32(4): 41-44.

 [28] M Zhao, C S Wu, S Y Jiang. Evaluating and Predicting the Collapsing Tendency of Fully Penetrated GTA Weld Pools[J]. Proceedings of the Institution of Mechanical Engineers, Part B, Journal of Engineering Manufacture. 2010, 224(11), 1 679-1 689.

 [29]赵明, 秦亚伟, 孙永兴. 全熔透钨极惰性气体保护电弧焊熔池表面变形动态过程的数值分析[J].机械工程学报, 2010, 46(4): 42-47.

 [30]孙永兴, 翟磊, 赵明. GMAW焊接熔池形状和表面变形的数值模拟[J]. 焊接学报, 2010, 31(10): 39-42.

 [31]赵明, 武传松, 孙永兴. 全熔透钨极惰性气体保护电弧焊熔池流动与传热动态过程的数值分析[J]. 机械工程学报, 2009, 45(9): 266-271.

 [32]赵明, 翟磊, 孙永兴. 全熔透GTAW熔池表面变形数值分析精度的改进[J]. 焊接学报, 2008, 29(11): 21-24.

 [33] Zhao Ming, Zhai Lei. Prediction of weld penetration extent in GTAW[J]. China Welding, 2008, 17(3): 34-39.

 [34] Zhao Ming, Li Ruiying. Numerical analysis of dynamic variation of weld pool geometry in fully-penetrated TIG Welding[J]. China Welding, 2008,17(2): 47-53.

 [35] 赵明, 贾晓燕, 孙永兴. 激光深熔焊三维瞬态温度场的数值模拟[J]. 焊接,2008, 52(11): 56-58.

 [36]赵明, 翟磊, 孙永兴. GMAW三维瞬态焊接热过程的数值模拟[J]. 焊接, 2008, 52(10): 28-31.

 [37]赵明, 武传松, 陈姬. 钨极氩弧焊熔透熔池塌陷倾向的预测[J]. 机械工程学报,2007, 43(6): 68-71.

 [38]赵明, 武传松, 胡庆贤. TIG焊接熔透熔池形状和表面变形的数值模拟[J]. 机械工程学报, 2006, 42(10): 203-208+214.

 [39] Zhao Ming, Chen Ji, Wu Chuansong. Predicting the occurrence tendency ofburn-through for fully-penetrated GTA weld pool[J]. China Welding, 2006, 15(4): 18-22.

 [40]赵明, 武传松, 陈茂爱. 焊接热过程数值分析中相变潜热的三种解决方案[J]. 焊接学报, 2006, 27(9): 55-58+ 62.

 [41]赵明, 武传松, 赵朋成. GTAW熔池形状数值模拟精度的改进[J]. 焊接学报. 2006, 27(3): 17-20+28.

 ◎学术报告

 [1] 赵明, 蒋淑英, 张晓豪, 范金峰. 超常热加工之傅里叶模型与非傅里叶模型及其应用现状与面临挑战. 第二十九次全国焊接学术会议, 武汉, 2025-10-102025-10-13. (邀请报告)

 [2] Ming Zhao, Lishuang Yao, Tao Xia, Zishen Qiao. Effect of Alternating Magnetic Field plus Inclined Welding Torch on the Microstructure and Properties of CMT-WAAM Aluminum-based Components with Highly Deviated Angle, 10th International Conference on Welding Science and Engineering (WSE 2025), Beijing, 2025-08-08 to 2025-08-11. (Invited Presentation)

 [3] 赵明. 交变磁场 + 焊枪倾角对CMT-WAAM铝基倾斜构件成形、组织和性能的调控. 第十二届中国北方焊接学术会议, 长春, 2025.07.25 - 27. (邀请报告)

 [4] Ming Zhao, Tao Xia, Zhishen Qiao, Hui Zhang. Effect ofarc torch angle and auxiliary magnetic field on the characteristics of CMT-WAAM aluminum alloyed components. The 4th International Symposium on Computer-Aided Welding Engineering and Additive Manufacturing (CAWE-AM 2024). 17-20 0ctober 2024, Jinan. (Invited Presentation)

 [5] 赵明, 林志港, 郑寒梅. 自支撑电弧熔丝增材制造(CMT-WAAM)构件倾斜度的调控及成形机理[R]. 第二届增材制造技术高峰论坛, 南京, 2023.09.23-24. (邀请报告)

 [6] 赵明, 封学志, 蒋淑英. 螺旋焊管的成形缺陷及复合能场的协同增效机制[R]. 2023年中国机械工程学会焊接分会青年工作者第五届学术研讨会, 威海, 2023.04.29-30. (邀请报告)

 [7] 赵明, 唐少彪, 封学志. 辅助磁场对X80钢螺旋埋弧焊接焊缝成形及接头性能的调控. 26次全国焊接学术会议——高效数字化焊接, 中国机械工程学会焊接分会主办, 2022.11.13-15, 成都. (邀请报告)

 [8] 王潇, 赵明, 唐少彪, 林志港. CMT+P/钢熔钎焊接过程及接头形性的调控. 26次全国焊接学术会议——高效数字化焊接. 中国机械工程学会焊接分会主办, 2022.11.13-15, 成都.

 [9] 林志港, 赵明, 唐少彪, 王潇. 自支撑CMT-WAAM焊道偏移角和焊枪倾角的实验研究与理论分析.首届全国增材制造技术高峰论坛, 机械工业信息研究院金属加工杂志社主办, 2022.11.26-28, 马鞍山.

 [10] Ming Zhao, Hongyuan Chen, Xuezhi Feng. Effect of Transverse assisted magnetic field on weld formation and joint quality in Spiral Submerged Arc Welding of steel linepipes. Oral Presentation in the Conference of AWS Professional program, 2021.9.20-23.

 ◎授权专利

[1]王炳明, 赵明, 蒋淑英, . 一种适用于焊条电弧焊半机械化焊接的重力焊接装置. 2020-11-20, ZL202020207865.6

[2]于牧冰, 赵明, 封学志, . 一种适用于焊接工艺的复合磁场发生装置. 2019-08-23, ZL201920350597.0

 [3]赵明, 魏飞, 范宁, .超高强度高韧性X120级管线钢环形焊缝的焊接工艺. 2018-10-09, CN201610348266.4

 [4]赵明, 王海燕, 魏飞, . 一种X80级管线钢环形焊缝的双丝焊接工艺. 2018-09-25, CN201610237502.5



»Name: Ming Zhao

»Department: School of Materials Science and Engineering

»Degree: Ph.D

»Title: Associate Professor

»Major:Materials Processing Engineering

»Mentor category: Master supervision

»Emailzhaoming08@upc.edu.cn

»Telephone86-15318790152

»Address: 66 Changjiang West Road, Qingdao City, Shandong Province PRC

»Overview:Ming Zhao, Associate Professor, Master supervision. Member of China Mechanical Engineering Society, Member of Computer Aided Welding Engineering of Welding Society, Member of Editorial Board of Metal Forming (Hot Working) and Welded Pipe & Tube. The main research fields are welding and joining of oil and gas pipelines and offshore platforms, wire arc additive manufacturing, and numerical simulation of material processing.  Responsible for and participated in more than 10 research projects, published more than 40 papers and granted 4 patents.

 ◎RESEARCH FIELDS

 1. Welding and Joining of Advanced Materials

 2. Additive Manufacturing

 3. Numerical Simulation and Intelligent Control

 ◎EDUCATION EXPERIENCE

 1. September, 1992 - June, 1996        Jilin University, Undergraduate.

 2. September, 2001 - December, 2006   Shandong University, Graduate.

 ◎WORK EXPERIENCE

 1. July, 1996 – August, 2001 Assistant Engineer, Chengdu Dazhonghua Welding Materials Co., Ltd.

 2. January, 2007 – November, 2009 Lecturer, School of Mechanical and Electronic Engineering, China University of Petroleum (East China)

 3. December, 2009-July, 2018 Associate Professor, School of Mechanical and Electronic Engineering, China University of Petroleum (East China)

 4. January, 2012- January, 2013 Visiting Scholar, The Ohio State University, USA

 5. August, 2018- present Associate Professor, School of Materials Science and Engineering, China University of Petroleum (East China)

 ◎ACADEMIC PART-TIME JOB

 1. Member of China Mechanical Engineering Society

 2. Member of Computer Aided Welding Engineering Committee of Welding Society

 3. Member of the Editorial Board of Metal Forming (Hot Working)

 4. Member of the Editorial Committee of Welded Pipe & Tube

 ◎TEACHING COURSES

 1. Transport Principles of Materials Processing

 2. High-Efficient Welding and Joining Processes

 3. Welding and Joining of Advanced Materials

 4. Robots Welding and Joining

 5. Mechanical Thermal Processing Practice

 6. Comprehensive Practice of Professional Foreign Language

 7. International Education Courses

 (1).Advanced Welding and Joining Processes (32 Hours)

 (2).Solid/Semi-Solid Materials Processing Technologies (32 Hours)

 (3).High Efficient Welding and Joining Processes (32 Hours)

 (4).Heat and Mass Transfer in Materials Science and Engineering (16 Hours)

 (5).Advanced Materials Processing (32 Hours)

 (6).Robot Perception, Localization and Navigation (32 Hours)

 ◎GUIDANCE AND SUPERVISION

 More than 20 graduate students have been instructed, and one has won an excellent graduate from Shandong Province.

 ◎RESEARCH PROJECTS

 1. Enterprise project: Manufacturing and testing of *** stealth material (January 2024-December 2024)

 2. Enterprise project: Research on automatic welding technology for ***bimetallic composite pipe (January 2021-December 2021)

 3. Natural Science Foundation of Shandong Province (ZR2020ME013)

 4. Natural Science Foundation of Shandong Province (ZR2018MEE020)

 5. Natural Science Foundation of Shandong Province (ZR2016EMM22)

 6. National Natural Science Foundation of China (51305461)

 7. Major Scientific Research Project of the Ministry of Education (313056)

 8. Independent Innovation Research Fund of the Ministry of Education (13CX02075A)

 9. Doctoral Program Fund of the Ministry of Education (20110133110003)

 10. Independent Innovation Research Plan of the Ministry of Education (11CX05003A)

 11. Natural Science Foundation of Shandong Province (ZR2011EMM015)

 12. Natural Science Foundation of Shandong Province (ZR2011EL023)

 13. Natural Science Foundation of Shandong Province (ZR2010EM073)

 14. Fundamental Research Project of Qingdao Science and Technology Bureau (09-1-3-37-jch)

 15. National Natural Science Foundation of China (50806082)

 16. Doctoral Research Fund of China University of Petroleum (East China) (Y070305)

 ◎GUIDE GRADUATE AND UNDERGRADUATE TO BE AWARDED

 1. 2025 Fan Jinfeng, Yao Lishuang, Shi Yuyang, Zhang Xiaohao to win the first prize in the 8th National Welding Innovation Competition for College Students

 2. 2024 Niu Fuwei, PanYunqian, et al to win the first prize in the 7th National Welding Innovation Competition for College Students

 3. 2024 Xia Tao to win excellent undergraduate thesis of UPC

 4. 2024 Qiao Zishen to win excellent undergraduate n thesis of UPC

 5. 2022 Chen Hongyuan, Wang Junjie, et al to win the second prize in the 5th National Welding Innovation Competition of College Students

 6. 2021 Song Yuanfang to win the excellent undergraduate thesis of UPC

 7. 2021 Chen Hongyuan to obtain the provincial innovation and entrepreneurship training project of college students

 8. 2020 Yu Mubing to obtain national innovation and entrepreneurship training project of college students

 9. 2019 Wu Tong to award an outstanding graduate student of Shandong Province

 10. 2018 Song Kaixing to obtain national innovation and entrepreneurship training project of college students

 11. 2018 Xiao Minggui to win excellent undergraduate thesis of CMSE, UPC

 12. 2014 I Bi Jing to win the excellent undergraduate thesis of UPC

 13. 2008 Zhai Lei to win the excellent undergraduate thesis of UPC

 14. 2007 Qin Yawei to win the excellent undergraduate thesis of UPC

 ◎AWARDED HONORS

 1. 2022-2024 Excellent reviewer of the Editorial Board of Metal Forming (Hot Working)

 2. 2021-2022 Outstanding trade union member of China University of Petroleum (East China)

 3. 2021-2022 Excellent class adviser of China University of Petroleum (East China)

 4. 2014-2015 Excellent class adviser of China University of Petroleum (East China)

 5. 2011-2012 Excellent class adviser of China University of Petroleum (East China)

 ◎PUBLISHED PAPERS

 [1] Ming Zhao, Shuying Jiang, Chuansong Wu, Lishuang Yao, Tao Xia. Synergistic regulation of alternating magnetic field and torch tilt angle for high-precision fabrication of self-supporting inclined aluminium alloy components via CMT-WAAM[J]. Journal of Materials Research and Technology, 2026, 42: 729-743.

 [2] Zhao Ming, Zhang Xiaohao, Fan Jinfeng, Shi Yuyang, Yao Lishuang, Wu Chuansong. Evolution and application of heat conduction theory in extreme thermal processing: from Fourier Heat Conduction Model to Non-Fourier Heat Conduction Model[J]. Journal of Materials Engineering., 2025, 53(9): 39-49.

 [3] Tang Shiyun, Zhao Ming, Ding Haozhen, et al. Microstructure and mechanical properties of NBG-GTAW joints of austenitic stainless steel for LNG [J]. Welding & Joining, 2025, (5): 44-53.

 [4] Jiang Shuying, Xu Hongming, Zhao Ming, Huang Wanqun. Effects of La content on microstructure and properties of Ni-Cr-Ti-La Laser-cladded and plasma-nitrided layers[J]. Transactions of The Indian Institute of Metals, 2025, 78: 162. https://doi.org/10.1007/s12666-025-03644-5

 [5] Jiang Shuying, Xu Hongming, Zhao Ming, Huang Wanqun. Effects of nitriding parameters on the microstructure and properties of laser-cladding and plasma-nitriding composite modified layers[J]. Bulletin of Materials Science, 2025, 48: 47. https://doi.org/10.1007/s12034-025-03404-7

 [6] Ming Zhao, Xiao Wang, Shaobiao Tang, Zhigang Lin, Hongyuan Chen. Determination and characterization of heat input, microstructure and performance in Cold Metal Transfer weld brazing of dissimilar AA6061 T6 to SS304 sheets. Transactions of the Indian Institute of Metals, 2023, 76: 1359–1369. https://doi.org/10.1007/s12666-022-02796-y.

 [7] Jiang Shuying, Cai Chang, Zhao Ming, Huang Wanqun. Microstructure and properties of Q235 steel/6061 aluminum alloy resistance spot welding joint based on high-entropy alloy interlayer. Transactions of the China Welding Institution. 2023, 44(7): 71-78.

 [8] Jiang Shuying, Zhang Junli, Zhao Ming. Microstructure and properties of copper/steel TIG welded joint based on high-entropy alloy interlayer. Journal of China University of Petroleum (Edition of Natural Science), 2023, 47(6): 154-161.

 [9] Ming Zhao, Xuezhi Feng, Zhaopeng Cui, Junjie Wang, Hongyuan Chen. Influence of transverse auxiliary magnetic field on weld formation and joint quality in spiral submerged arc welding of X80 steel linepipe. Welding in the World, 2022, 66(12): 2497–2508. https://doi.org/10.1007/s40194-022-01371-9.

 [10] Chen Shiwei, Tang Shiyun, Zhao Ming, Wei Xumin. Research on three times welding repair technology of important joints for offshore windfarm jacket. Welding Technology, 2022, 51(11): 62-67+114.

 [11] Tang Shiyun, Zhao Ming, Wei Sheng, Wei Xumin, Li Zhenhua. Welding process and performance evaluation of JCOE steel pipe for offshore windfarm jacket. Welding and Joining, 2022, (10): 59-64.

 [12] Zhao Ming, Li Qing, Song Huiqin, Yu Zhu, Yang Peiqing, Guo Shenglong, Geng Huilong. Research status and development trend of welding technology for pipeline steels. Metal Forming (Hot Working), 2022, (9): 21-25+58.

 [13] Ming Zhao; Junxu Chen; Mubing Yu; et al. Effect of transverse magnetic field on weld formation and microstructure & properties of high-speed hot-wire tungsten inert gas welding joints. Science and Technology of Welding and Joining, 2020, 25(6): 521-528.

 [14] Shuying Jiang, Hongming Xu, Ming Zhao, Yongxing Sun. Microstructure and properties of Cr-Ni-Ti-RE cladded-nitrided composite modified layers on N80 steel. Surface and Coatings Technology, 2019, 361: 231-239.

 [15] Wenhao Wu, Ming Zhao, Haiyan Wang, et al. Twin-Wire Pulsed Tandem Gas Metal Arc Welding of API X80 Steel Linepipe. The International Journal of Corrosion, 2018, DOI: 10.1155/2018/7284246.

 [16] Zhao Ming, Wu Tong, Wei Fei, et al. Temperature Field and Fluid Flow of Multi-wire Tandem Submerged Arc Welding of Longitudinal Spiral Weld Seam. Proceedings of the WSE & CAWE, Jinan, 2017.10.18-20.

 [17] M. Zhao, F. Wei, W. Q. Huang, et al. Experimental and numerical investigation on combined girth welding of API X80 pipeline steel. Science and Technology of Welding and Joining, 2015, 20(7): 622-630.

 [18] Wan Fuwei; Guo Xinfang; Zhao Ming; Study on GTAW welding technology of S32205 duplex stainless steel. Welding Technology, 2021, 50(10): 60-62.

 [19] Feng Xuezhi, Zhao Ming, Cao Meiqing. Study on Microstructure and Properties of Fe Based ZrB2-ZrC Compound Coating on Q235 Steel by Plasma Cladding. Hot Working Technology, 2019, 48(16): 106-110+115.

 [20] Wan Fuwei, Guo Xinfang, Zhao Ming, et al. Analysis of temperature field and joint microstructure in friction stir welding of 2A12 aluminum alloy. Welded pipe, 2016, 39(9): 13-18.

 [21] Zhao Ming, Wang Haiyan, Wan Fuwei, et al. Numerical analysis of three-wire tandem submerged arc welding grade X80 pipeline steel. Transactions of the China Welding Institution, 2014, 35(10): 17-20.

 [22] Ming Zhao, Haiyan Wang, Fei Wei, Detong Luo. Numerical and experimental investigation into single-wire and multi-pass welding of super high-strength low-alloy pipeline steel. Proceedings of 4thJapan-China Workshop on Welding Thermo-Physics, Osaka, Japan, 2014, 21-24.

 [23] Li Ruiying, Zhao Ming, Wu Chunmei. Determination of shape parameters of double ellipsoid heat source model in numerical simulation based on SYSWELD software. Transactions of the China Welding Institution, 2014, 35(10): 93-96.

 [24] Zhao Ming, Luo Detong, Wang Haiyan. Finite element analysis on temperature field and weld profile of carbon dioxide gas shielded arc welding. Journal of Mechanical Engineering, 2013, 49(14): 80-85.

 [25] Zhao Ming, Du Dandan, Luo Tongtong. Effects of welding parameters on temperature field in GTAW. Transactions of the China Welding Institution, 2013, 34(3): 21-24.

 [26] Zhao Ming, Zhang Xingyuan, Wan Fuwei. Effect of the distribution parameter of heat source on temperature profiles in GTAW. China Welding, 2012, 21(4): 20-25.

 [27] Li Ruiying, Zhao Ming, Zhou Hongyan. Finite element analysis on 3-D molten pool geometry for GTAW based on SYSWELD software. Transactions of the China Welding Institution, 2011, 32(4): 41-44.

 [28] M Zhao, C S Wu, S Y Jiang. Evaluating and Predicting the Collapsing Tendency of Fully Penetrated GTA Weld Pools. Proceedings of the Institution of Mechanical Engineer s, Part B, Journal of Engineering Manufacture. 2010, 224(11), 1 679-1 689.

 [29] Zhao Ming, Qin Yawei, Sun Yongxing. Numerical analysis of dynamic surface-deformation of fully-penetrated gas tungsten arc welding molten pool. Journal of Mechanical Engineering, 2010, 46(4): 42-47.

 [30] Sun Yongxing, Zhai Lei, Zhao Ming. Numerical simulation of weld pool geometry and surfaces deformation in GMAW. Transactions of the China Welding Institution, 2010, 31(10): 39-42.

 [31] Zhao Ming, Wu Chuansong, Sun Yongxing. Numerical analysis of dynamic fluid flow and heat transfer in fully-penetrated GTAW weld pool. Journal of Mechanical Engineering, 2009, 45(9): 266-271.

 [32] Zhao Ming, Zhai Lei, Sun Yongxing. Improvement on numerical analysis precision of surface deformation of molten pool in fully penetrated GTAW. Transactions of the China Welding Institution, 2008, 29(11): 21-24.

 [33] Zhao Ming, Zhai Lei. Prediction of weld penetration extent in GTAW. China Welding, 2008, 17(3): 34-39.

 [34] Zhao Ming, Li Ruiying. Numerical analysis of dynamic variation of weld pool geometry in fully-penetrated TIG Welding. China Welding, 2008,17(2): 47-53.

 [35] Zhao Ming, Jia Xiaoyan, Sun Yongxing. Numerical simulation of transient 3-D temperature field in laser deep-penetration welding. Welding and Joining, 2008, 52(11): 56-58.

 [36] Zhao Ming, Zhai Lei, Sun Yongxing. Numerical simulation of three-dimensional transient temperature in GMAW. Welding and Joining, 2008, 52(10): 28-31.

 [37] Zhao Ming, Chuan Song, Chen Ji. Prediction of the tendency of molten pool collapse in TIG penetration. Journal of Mechanical Engineering, 2007, 43(6): 68-71.

 [38] Zhao Ming, Wu Chuansong, Hu Qingxian. Predicting of the collapsing for completely penetrated GTA weld pool. Journal of Mechanical Engineering, 2006, 42(10): 203-208+214.

 [39] Zhao Ming, Chen Ji, Wu Chuansong. Predicting the occurrence tendency of burn-through for fully-penetrated GTA weld pool. China Welding, 2006, 15(4): 18-22.

 [40] Zhao Ming, Wu Chuansong, Chen Maoai. Solutions for latent heat of phase change in numerical analysis of arc welding. Transactions of the China Welding Institution, 2006, 27(9): 55-58+62.

 [41] Zhao Ming, Wu Chuansong, Zhao Pengcheng. Improvement on numerical simulation precision of GTAW weld pool geometry. Transactions of the China Welding Institution. 2006,27 (3): 17-20+28.

 ◎AUTHORIZED PATENTS

 [1] Wang Bingming, Zhao Ming, Jiang Shuying, et al. A gravity welding device suitable for semi-mechanized manual metal arc welding.2020-11-20, ZL 2020207865.6.

 [2] Yu Mubing, Zhao Ming, Feng Xuezhi, et al. A hybrid magnetic field generator suitable for fusion welding process.2019-08-23, ZL 201920350597.0.

 [3] Zhao Ming, Wei Fei, Fan Ning, et al. Girth welding technology of X120 pipeline steel with ultra-high strength and high toughness. 2018-10-09, CN20161048266.4.

 [4] Zhao Ming, Wang Haiyan, Wei Fei, et al. A double-wire welding process for circumferential weld of X80 pipeline steel.2018-09-25, CN20161037502.5.