徐連勇 教授 -天津大學(xué)

徐連勇 教授

材料加工系

電話： 13920370051

Email： xulianyong@tju.edu.cn

研究所： 焊接與先進(jìn)制造技術(shù)研究所

個人簡歷

教育經(jīng)歷：

2004.03-2007.03，天津大學(xué)，材料加工工程，博士

2001.09-2004.02，天津大學(xué)，材料加工工程，碩士

1994.09-1998.06，蘭州鐵道學(xué)院（現(xiàn)蘭州交通大學(xué)），機(jī)車車輛工程，學(xué)士

工作經(jīng)歷：

2014.07-至今， 天津大學(xué)，材料學(xué)院材料加工系，教授，系主任

2013.07-2014.01，新加坡南洋理工大學(xué)，材料學(xué)院，客座研究員

2010.09-2011.03，美國維吉尼亞理工大學(xué)，材料學(xué)院，訪問學(xué)者

2009.07-2014.06，天津大學(xué)，材料學(xué)院材料加工系，副教授

1998.07-2001.08，鐵道部唐山機(jī)車車輛廠（現(xiàn)中車唐山機(jī)車車輛有限公司），助理工程師

學(xué)術(shù)兼職

中國焊接學(xué)會常務(wù)理事

中國焊接學(xué)會焊接力學(xué)及結(jié)構(gòu)設(shè)計(jì)與制造專委會主任委員

中國焊接學(xué)會青年工作委員會副主任委員

中國機(jī)械工程學(xué)會高級會員

國際焊接學(xué)會焊接接頭性能與斷裂預(yù)防專委會（C-X）、壓力容器與管道專委會（C-XI）委員

中國電機(jī)工程學(xué)會電站焊接專委會委員

神華國華電力“院士專家工作站”進(jìn)站專家


主要榮譽(yù)

教育部優(yōu)秀新世紀(jì)人才（2011年）

天津市131創(chuàng)新型人才工程第一層次（2017年）

天津大學(xué)北洋青年學(xué)者（2013年）

天津大學(xué)優(yōu)秀共產(chǎn)黨員（2011年）

天津大學(xué)教工先鋒號（2015年）

天津大學(xué)研究生“我心目中的好導(dǎo)師”（2013年）

研究方向

一直致力于焊接結(jié)構(gòu)力學(xué)及結(jié)構(gòu)設(shè)計(jì)與制造的前沿研究，面向深海油氣、高效潔凈火電、新一代核電、新能源等行業(yè)在高溫、低溫、疲勞、腐蝕等極端復(fù)雜環(huán)境下工作的能源裝備，長期從事焊接結(jié)構(gòu)強(qiáng)度與壽命設(shè)計(jì)、缺陷評定與壽命評估、高性能長壽命焊接制造、增材制造等方面的基礎(chǔ)理論與應(yīng)用技術(shù)研究，具體方向如下：

（1）極端環(huán)境條件下無缺陷焊接結(jié)構(gòu)高溫強(qiáng)度壽命設(shè)計(jì)與評價

開發(fā)蠕變、疲勞及復(fù)合條件下高等級耐熱鋼、不銹鋼、復(fù)合釬料等先進(jìn)材料的變形、損傷本構(gòu)模型與壽命預(yù)測模型，建立無缺陷焊接結(jié)構(gòu)的強(qiáng)度設(shè)計(jì)與壽命評估方法，服務(wù)于我國新一代高效潔凈超超臨界火電、壓水堆核電、快堆核電等發(fā)電機(jī)組高溫管道的選材、設(shè)計(jì)、焊接、評價與評估。

（2）極端復(fù)雜環(huán)境條件下含缺陷焊接結(jié)構(gòu)的斷裂評定與壽命評估

開發(fā)蠕變裂紋萌生與擴(kuò)展壽命預(yù)測模型、蠕變-疲勞交互損傷模型與裂紋擴(kuò)展預(yù)測模型，考慮拘束效應(yīng)和殘余應(yīng)力的定量影響，發(fā)展高溫焊接管道缺陷壽命的高精準(zhǔn)評估方法與行業(yè)標(biāo)準(zhǔn)，服務(wù)于超超臨界火電機(jī)組高溫管道的運(yùn)行監(jiān)督與壽命管理；研究考慮拘束效應(yīng)和載荷歷史的彈塑性斷裂評定方法，開發(fā)極端大塑性應(yīng)變條件下深海油氣管道全壽期斷裂評定方法，實(shí)現(xiàn)高精準(zhǔn)的缺陷斷裂評定與壽命評估，建立行業(yè)標(biāo)準(zhǔn)，服務(wù)于深海油氣平臺與海底管道制造、安裝、服役中的焊接缺陷控制與評價。

（3）高性能長壽命焊接制造

基于TIG、MIG、CMT、激光焊、激光填絲焊、激光電弧復(fù)合焊等先進(jìn)焊接方法開展自動化、智能化焊接技術(shù)研究；研究先進(jìn)鐵素體耐熱鋼焊接接頭早期失效機(jī)理，開發(fā)防止早期失效的焊接方法與工藝，服務(wù)于我國新一代超超臨界機(jī)組蒸汽管道的焊接制造；研究深水J-lay鋪設(shè)、Reel-lay鋪設(shè)海底管道抗腐蝕、抗大變形的高效焊接技術(shù)，服務(wù)于我國南海深海油氣開發(fā)戰(zhàn)略；研究超大型結(jié)構(gòu)件的焊接變形控制技術(shù)與機(jī)器人焊接技術(shù)，服務(wù)于海上油氣平臺、港口機(jī)械等大型結(jié)構(gòu)智能焊接制造的升級。

（4）增材制造

基于激光選區(qū)熔化、激光熔覆等方法開展新型超高溫合金、鋁合金、不銹鋼及結(jié)構(gòu)件的增材制造原理與技術(shù)研究，服務(wù)于火電、核電、航空、航天、海洋工程等高價值部件的3D打印工程應(yīng)用。

承擔(dān)項(xiàng)目

1.國家重點(diǎn)研發(fā)計(jì)劃，2017YFB1303300，面向港口機(jī)械超大型構(gòu)件的機(jī)器人制造技術(shù)與系統(tǒng)集成及應(yīng)用示范，2017.12-2020.11，1396萬元，在研，主持

2.國家海洋戰(zhàn)略性新興產(chǎn)業(yè)專項(xiàng)，BHSF2017-22，海洋高端裝備焊接智能制造產(chǎn)業(yè)鏈協(xié)同創(chuàng)新和構(gòu)建，2017.01-2019.12，2005萬元，在研，主持

3.國家自然科學(xué)基金面上項(xiàng)目，51475326，含體積缺陷的高溫焊接管道壽命評估理論與方法研究，2015.01-2018.12，82萬元，在研，主持

4.國家自然科學(xué)基金青年項(xiàng)目，50805102，基于C*-Q雙參量的高溫下含裂紋焊接接頭缺陷評定與預(yù)測方法研究，2009.01-2011.12，21萬元，已結(jié)題，主持

5.國家海洋戰(zhàn)略性新興產(chǎn)業(yè)專項(xiàng)，CXSF2014-12，深水海底管道焊接綜合試驗(yàn)平臺，2014.01-2016.12，1726萬元，已結(jié)題，技術(shù)負(fù)責(zé)人

6. 600MW示范快堆工程國家核科技重大專項(xiàng)（子課題），2015-KGB-I-FWCG-0019，快堆高溫鈉管道焊接接頭蠕變損傷分析與壽命評估研究，2015.11-2018.12，610.86萬元，在研，主持

7. 600MW示范快堆工程國家核科技重大專項(xiàng)（子課題），2016-DGB-I-KYSC-0032，鈉管道標(biāo)準(zhǔn)庫研發(fā)項(xiàng)目-特殊性能與壽命評估研究，2016.11-2018.12，433.3萬元，在研，主持

8.大型先進(jìn)壓水堆核電站CAP1400示范工程國家重大專項(xiàng)（子課題），2011ZX06002，蒸汽發(fā)生器出口接管與泵殼異種鋼焊接接頭殘余應(yīng)力、斷裂韌性與安全評估，2014.10-2015.12,180萬元，已結(jié)題，主持

9.天津市科技興海項(xiàng)目，KJXH2012-08，卷管式鋪管管道高效焊接技術(shù)與大型彎管模擬裝置開發(fā)，2012.06-2015.05,170萬元，已結(jié)題，主持

10.天津市科技支撐計(jì)劃重點(diǎn)項(xiàng)目，11ZCKFGX03000，電動汽車逆變器新型大功率IGBT模塊集成與制造關(guān)鍵技術(shù)，2011.04-2014.03，75萬元，已結(jié)題，主持

11.教育部新世紀(jì)優(yōu)秀人才支持計(jì)劃，NCET-11-0375，材料先進(jìn)連接技術(shù)及可靠性，2012.01-2014.12，50萬元，已結(jié)題，主持

12.天津市自然科學(xué)基金，13JCYBJC18200，深冷處理改善航空鈦合金電子束焊接接頭性能研究，2013.04-2016.03,10萬元，已結(jié)題，主持

13.天津市自然科學(xué)基金，JCYBJC09100，熱障涂層界面斷裂行為表征與結(jié)構(gòu)完整性評定研究，2008.04-2011.03,10萬元，已結(jié)題，主持

14.國家自然科學(xué)基金面上項(xiàng)目，50975196，循環(huán)大塑性應(yīng)變下含環(huán)焊縫高強(qiáng)度管道的斷裂評定方法研究，2010.01-2012.12，38萬元，已結(jié)題，參加（第二）

15.國家自然科學(xué)基金面上項(xiàng)目，50275107，考慮微觀塑性損傷的焊接接頭斷裂行為預(yù)測與評定，2013.01-2015.12，21萬元，已結(jié)題，參加（第二）

16.科技部科研院所技術(shù)開發(fā)專項(xiàng)資金項(xiàng)目（子課題），NCSTE-2006-178，高等級耐熱鋼IV型裂紋開裂機(jī)理及防止措施，2007.05-2010.12，15萬元，已結(jié)題，主持

以及中海油、神華國華電力公司、國家電網(wǎng)、中國一重等央企橫向技術(shù)開發(fā)與服務(wù)等科研項(xiàng)目50余項(xiàng)，累計(jì)科研經(jīng)費(fèi)6000余萬元。

標(biāo)志性成果

科技獎勵：

（1）2018年，中國機(jī)械工業(yè)科學(xué)技術(shù)一等獎，深海油氣管道和平臺高效高性能焊接與評估關(guān)鍵技術(shù)及應(yīng)用，排名第1

（2）2017年，天津市科技進(jìn)步一等獎，深海油氣管道全壽命評估與焊接制造關(guān)鍵技術(shù)開發(fā)及應(yīng)用，排名第1

（3）2012年，天津市科技進(jìn)步一等獎，超（超）臨界機(jī)組關(guān)鍵高溫設(shè)備完整性與壽命評估技術(shù)及應(yīng)用，排名第1

（4）2010年，教育部科技進(jìn)步一等獎，基于局部法的大型焊接結(jié)構(gòu)完整性評定技術(shù)與應(yīng)用，排名第2

（5）2016年，第十三屆天津青年科技獎

（6）2014年，中國電力科學(xué)技術(shù)二等獎，超超臨界機(jī)組管系應(yīng)力在線監(jiān)測系統(tǒng)研發(fā)，排名第3

（7）2010年，中國電力科學(xué)技術(shù)二等獎，超超臨界機(jī)組P92管道焊接接頭性能評價及應(yīng)用技術(shù)研究，排名第3

（8）2007年，天津市科技進(jìn)步二等獎，電力系統(tǒng)含缺陷承壓結(jié)構(gòu)完整性評定方法及應(yīng)用，排名第2

參編專著：

（1）《中國焊接1994-2016》第六章 焊接結(jié)構(gòu)（中英文），中國機(jī)械工程學(xué)會焊接學(xué)會，機(jī)械工業(yè)出版社，2017年；

（2）《中國焊接技術(shù)路線圖》第九章 焊接力學(xué)與結(jié)構(gòu)制造技術(shù)，中國機(jī)械工程學(xué)會焊接學(xué)會，機(jī)械工業(yè)出版社，2016年；

（3）《國際焊接學(xué)會（IIW）研究進(jìn)展》（C-X專委會、C-XI專委會），中國焊接學(xué)會，2017年.

近5年代表性論文：

2018年

[1] Dongquan Wu,Hongyang Jing,Lianyong Xu*,LeiZhao, Yongdian Han,Two-parameter approach of creep crack initiation times considering the constraint effect induced by specimen geometry,Theoretical and Applied Fracture Mechanics, 2018, 96: 31-44.

[2]Lianyong Xu,Jianying Rong, Lei Zhao, Hongyang Jing, Yongdian Han, Creep-fatigue crack growth behavior of G115 steel at 650 °C,Materials Science & Engineering A, 2018, 726: 179~186.

[3] Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Analytical approaches of creep crack initiation prediction coupled with the residual stress and constraint effect,European Journal of Mechanics / A Solids, 2018, 71: 1~15.

[4] Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Theoretical and numerical analysis of the creep crack initiation time considering the constraint effects for pressurized pipelines with axial surface cracks,International Journal of Mechanical Sciences, 2018, 141: 262~275.

[5] Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Theoretical and numerical analysis of creep crack initiation combined withprimary and secondary stresses,Theoretical and Applied Fracture Mechanics, 2018, 95: 143~154.

[6] Yu Zhang, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao, Dengfeng Wang, Bo Xiao, Design and performance of weld filler metal to matchan advanced heat-resistant Fe-Cr-Ni alloy,Materials Science & Engineering A, 2018, 721: 103-116.

[7] Yu Zhang, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao, Bo Xiao, Microstructure and mechanical performance of welded joint between anovel heat-resistant steel and Inconel 617 weld metal,MaterialsCharacterization, 2018, 139: 279-292.

[8]Lianyong Xu, Lei Zhao, Hongyang Jing, Yongdian Han, Characterization of the creep interaction effect for twin semi-elliptical surface cracks undercombined tension and bending loading,Engineering Fracture Mechanics, 2018, 192: 148~162.

[9] Bo Xiao,Lianyong Xu*,Lei Zhao, Yongdian Han, Kai Song, Transientcreep behavior of a novel tempered martensite ferritic steel G115,MaterialsScience and Engineering A, 2018, 716: 284~295.

[10]Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Numerical analysis of the creep crack constraint effects and the creep crack initiation for pressurized pipelines with circumferential surface cracks,Advances in Engineering Software, 2018, 115: 40~51.

[11]Xiaoxin Zhao, Hongyang Jing,Lianyong Xu*,Lei Zhao, Jiangzhong Huang, A modified strain-controlled reference stress approach for submarine pipelines under large-scale plastic strain--online,Advances in EngineeringSoftware, 2018, 119: 12~20.

[12]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,Xiaoqing Lv, Jianyang Zhang, Influence of heat input in electron beam process on microstructure and properties of duplex stainless steel welded interface,Applied Surface Science, 2018, 435: 352~366.

[13]Bo Xiao,Lianyong Xu*,Lei Zhao, Yongdian Han, Yu Zhang, Creep properties, creep deformation behavior, and microstructural evolution of 9Cr-3W-3Co-1CuVNbB martensite ferritic steel,Materials Scienceand Engineering A, 2018, 711: 434~447.

[14]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,Xiaoqing Lv, Jianyang Zhang, The impact of annealing temperature on improving microstructure and toughness of electron beam welded duplex stainless steel,Journal of Manufacturing Processes, 2018, 31: 568~582.

[15]Yongdian Han, Siming Zhang,Lianyong Xu*,The fabrication of highly conductive and flexible Ag patterning through baking Ag nanosphere-nanoplate hybrid ink at a low temperature of 100 degrees C,Nanotechnoloy, 2018, 29(13): 135301.

[16]Lianyong Xu, Shuting Zhang, Yongdian Han, Lixia Wang, Indentation Size Effect on Ag Nanoparticle-Modified Graphene/Sn-Ag-Cu Solders,Journal ofElectronic Materials, 2018, 47(1): 612~619.

[17]Lei Zhao, Zunyi Zhao,Lianyong Xu*,Yongdian Han, Hongyang Jing, Assessment of creep interaction of double elliptical cracks at elevated temperatures using numerical analysis,Arch Appl Mech, 2018, 88(5): 691-703.

[18]Yongxin Lu, Hongyang Jing,Lianyong Xu*,Yongdian Han, A finite element model of carbon steel welded joint corrosion under plastic strain,Materials and Corrosion-Werkstoffe und Korrosion, 2018, 69(2): 227~238.

[19]Y.C. Xu, H.Y. Jing,L.Y. Xu*,Q.S. Jia, Y.D. Han, Microstructures and mechanical properties of friction hydro-pillar processing overlap welding in API 5L X65 pipeline steel,Welding in the World, 2018, 62(2): 325-338.

[20]Lianyong Xu, Hongyang Jing, Yongdian Han, Effect of welding on the corrosion behavior of X65/Inconel 625 in simulated solution,Welding in theWorld, 2018, 62(2): 363-375.

[21]Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Investigation on creep crack initiation prediction considering constraint effect using constraint parameter Q,Theoretical and Applied Fracture Mechanics, 2018, 96: 631-641.

[22]Pengyu Jia, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,Amodified engineering critical assessment method for deeply-embedded cracks inmetallic pipelines subjected to large plastic strain,EngineeringFractureMechanics, DOI: 10.1016/j.engfracmech.2017.11.024

[23]Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Creep crack initiation prediction considering constraint effect for pressurized pipelines with circumferential surface cracks,Fatigue Fracture Engineering Materials Structures,2018, 41(9): 1900-1917.DOI: 10.1111/ffe.12829.

[24]Hongyang Jing, Zhenxuan Luo,Lianyong Xu*,Lei Zhao, Yongdian Xu,Low cycle fatigue behavior and microstructure evolution of a novel 9Cr–3W–3Co tempered martensitic steel at 650 °C,Materials Science & Engineering A, 2018, 731: 394-402.

[25]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,Effect of post-weld heat treatment on microstructure evolution and pitting corrosion resistance of electron beam-welded duplex stainless steel,Corrosion Science, 2018, 141: 30-45.

[26]Zhengxin Tang,Hongyang Jing,Lianyong Xu*,Lei Zhao,Yongdian Han,Bo Xiao,Yu Zhang,Haizhou L,Creep-fatigue crack growth behavior of G115 steel under different hold time conditions,International Journal of Fatigue, 2018,116: 572-583.

[27]Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han, Analytical and Numerical Investigations of Creep Crack Initiation Considering the Load-Independent Constraint Parameter Q*,Arch Appl Mech, 2018, doi: 10.1007/s00419-018-1433-3.

[28]Lei Zhao*,Lianyong Xu*,Zhifang Gao,Yongdian Han,Hongyang Jing,Characterization crack growth behavior in creep-fatigue loading conditions through different specimen geometries,International Journal of Mechanical Sciences, 2018,145: 246-257.

[29]Yingxin Zhao,Lianyong Xu, Effect of blunt nanocracks on the splitting transformation of grain boundary dislocation piled up at triple junctions,International Journal of Solids and Structures, 2018,141-142: 232-244.

[30]Qifeng Li,Yingxin Zhao*,Lianyong Xu*,Effect of nanovoid on grain boundary migration and disclinated cracking in nanocrystalline materials,International Journal of Solids and Structures, 2018,10.1016/j.ijsolstr.2018.07.016.

[31]Yang Zhang, Xiaoqing Lv*,Lianyong Xu*, Hongyang Jing, Yongdian Han, A segmentation planning method based on the change rate of cross-sectional area of single V-groove for robotic multi-pass welding in intersecting pipe-pipe joint,The International Journal of Advanced Manufacturing Technology,https://doi.org/10.1007/s00170-018-2932-7.

[32]Dongquan Wu, Hongyang Jing,Lianyong Xu*,Lei Zhao, Yongdian Han,Enhanced models of creep crack initiation prediction coupled the stress-regime creep properties and constraint effect,European Journal of Mechanics / A Solids, 2018,DOI: 10.1016/j.euromechsol.2018.11.010

[33]Bo Xiao,Lianyong Xu*,Lei Zhao, Yongdian Han,Deformation-mechanism-based creep model and damage mechanism of G115 steel over a wide stress range,MaterialsScience and Engineering A, 2018, DOI:10.1016/j.msea.2018.11.083.

[34]Yu Zhang, Hongyang Jing,Lianyong Xu*, Lei Zhao, Yongdian Han,Creep Behavior and Life Assessment of a Novel Heat-Resistant Austenite Steel and Its Weldment,ActaMetallurgica Sinica (English Letters) ,2018, Accepted.

[35]Qifeng Li,Yingxin Zhao*,Lianyong Xu*,Effect of nanovoid on grain boundary migration and disclinated cracking in nanocrystalline materials,International Journal of Solids and Structures, 2018,155:140-154.



2017年

[1] Hongyang Jing, Dingbang Su,Lianyong Xu*, Lei Zhao, Yongdian Han, Ruiwen Sun，F(xiàn)inite element simulation of creep-fatigue crack growth behavior for P91 steel at 625°C considering creep-fatigue interaction,International Journal of Fatigue, 2017, 98: 41~52.

[2]Lianyong Xu, Lei Zhao, Zhifang Gao, Yongdian Han, A novel creep-fatigue interaction damage model with the stress effect to simulate the creep-fatigue crack growth behavior,International Journal of Mechanical Sciences, 2017, 130: 143~153.

[3] Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han, Lei Zhao,The influence of microstructural evolution on selective corrosion in duplex stainless steel flux-cored arc welded joints,Corrosion Science, 2017, 120: 194~210.

[4]Lianyong Xu, Lei Zhao, Yongdian Han, Hongyang Jing, Zhifang Gao, Characterizing crack growth behavior and damage evolution in P92 steel undercreep-fatigue conditions,International Journal of Mechanical Sciences, 2017, 134: 63~74.

[5]Lianyong Xu, Lei Zhao, Yongdian Han, Hongyang Jing,Evaluation ofmultiple cracks interaction effect subjected to biaxial tension under creepregime,International Journal of Mechanical Sciences, 2017, 122: 203~214.

[6] Pengyu Jia, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,A modified fracture assessment method for pipelines under combined inner pressure and large-scale axial plastic strain,Theoretical and Applied Fracture Mechanics, 2017, 87: 91~98.

[7] Pengyu Jia, Hongyang Jing, Lianyong Xu*, Yongdian Han, Lei Zhao,Investigation on plastic eta factors for SE(T) specimens with undermatched weld metal based on plane strain finite element analysis, International Journal of Mechanical Sciences, 2017, 122: 192~202.

[8]Bo Xiao,Lianyong Xu, Lei Zhao, Hongyang Jing, Yongdian Han, Zhengxin Tang, Microstructure evolution andfracturemechanism of a novel 9Crtempered martensite ferritic steel during short-term creep,Materials Scienceand Engineering A, 2017, 707: 466~477.

[9]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han, ZhanqiGao; Lei Zhao, Jianli Zhang, Microstructural characterization and electronbackscatter diffraction analysis across the welded interface of duplexstainless steel,Applied Surface Science, 2017, 413: 327~343.

[10]Bo Xiao,Lianyong Xu*, Lei Zhao, Hongyang Jing, Yongdian Han,Tensile mechanical properties, constitutive equations, and fracture mechanisms of anovel 9% chromium tempered martensitic steel at elevated temperatures,Materials Science & Engineering A, 2017, 690: 104~119.

[11]Yu Zhang, Hongyang Jing,Lianyong Xu*, Lei Zhao, Yongdian Han,Yingxin Zhao,High-temperature deformation and fracture mechanisms of anadvanced heat resistant Fe-Cr-Ni alloy,Materials Science & Engineering A, 2017, 686: 102~112.

[12]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han,Effects of nitrogen in shielding gas on microstructure evolution andlocalized corrosion behavior of duplex stainless steel welding joint,AppliedSurface Science, 2017, 404: 110~128.

[13]Lianyong Xu, Xingfu Zhang, Lei Zhao, Yongdian Han, Hongyang Jing,Characterization of creep crack-tip constraint levels for pressurized pipelineswith axial surface cracks,Advances in Engineering Software, 2017.12, 114:98~109.

[14]Hao Wang, Hongyang Jing,Lianyong Xu*, Lei Zhao, Yongdian Han, Xiaoqing Lv,Dislocation structure evolution in 304L stainless steel and weldjoint during cyclic plastic deformation,Materials Science & Engineering A, 2017, 690: 16~31.

[15]Hao Wang, Hongyang Jing,Lianyong Xu*, Lei Zhao, Yongdian Han, Xiaoqing Lv,Uniaxial ratcheting behaviour of 304L stainless steel and ER308Lweld joints,Materials Science and Engineering A, 2017, 708: 21~42.

[16]H.Y. Jing, H.J. Guo, L.X. Wang,L.Y. Xu*, J. Wei, Y.D. Han,Influence of Ag-modified graphene nanosheets addition into Sn-Ag-Cu solders on theformation and growth of intermetallic compound layers,Journal of Alloys andCompounds, 2017, 702: 669~678.

[17]Yu Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han, Lei Zhao, Jun Liang,Microstructure and texture study on an advanced heat-resistant alloyduring creep,Materials Characterization, 2017, 130: 156~172.

[18]Yachen Xu, Hongyang Jing,Lianyong Xu*, Yongdian Han, Microstructures and Mechanical Properties of Friction Tapered Stud Overlap Welding for X65 Pipeline Steel Under Wet Conditions,Journal of Materials Engineering and Performance, 2017, 26(8): 4092~4103.

[19]Yongxin Lu, Hongyang Jing,Lianyong Xu*, Yongdian Han,Corrosion behavior of pipeline steel welds in simulated produced water with different CO2 partial pressures under high temperature,Materials Testing, 2017, 59(4): 348~354.

[20]Yongxin Lu, Hongyang Jing,Lianyong Xu*, Yongdian Han,Effects ofcharging conditions on the hydrogen related mechanical property degradation ofa 3 Cr low alloyed steel,Materials Testing, 2017, 59: 233~238.

[21]Yongxin Lu, Hongyang Jing,Lianyong Xu*, Yongdian Han,Influence of surface microstructure and chemical compositions on groovingcorrosion of carbon steel welded joints,Materials Testing, 2017, 59(11-12):957~964.

[22]Lianyong Xu, Keke Ge, Hongyang Jing, Lei Zhao, Xiaoqing Lv, Yongdian Han,Prediction of residual stresses in electron beam welded Ti-6Al-4V plates,Materials Testing, 2017, 59(4): 323~329.

[23]Zhiqiang Zhang, Hongyang Jing, Lianyong Xu*,Yongdian Han, LeiZhao, Jianli Zhang,Influence of microstructure and elemental partitioning onpitting corrosion resistance of duplex stainless steel welding joints, AppliedSurface Science, 2017, 394: 297~314.

[24]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han, GuoluLi, Lei Zhao,Investigation on Microstructure and Impact Toughness ofDifferent Zones in Duplex Stainless Steel Welding Joint,Journal of MaterialsEngineering and Performance, 2017, 26: 134~150.

[25]Lei Zhao,Lianyong Xu, Kamran Nikbin,Predicting failure modes increep and creep-fatigue crack growth using a random grain/grain boundaryidealised microstructure meshing system,Materials Science & Engineering A, 2017, 704: 274~286.

2016年

[1]Lianyong Xu, Xingfu Zhang, Lei Zhao, Yongdian Han, Hongyang Jing, Quantifying the creep crack-tip constraint effects using aload-independent constraint parameter Q*,International Journal of MechanicalSciences, 2016, 119: 320~332.

[2]Pengyu Jia, Hongyang Jing,Lianyong Xu*,Yongdian Han, Lei Zhao,Amodified reference strain method for engineering critical assessment of reeledpipelines,International Journal of Mechanical Sciences, 2016, 105: 23~31.

[3]Lianyong Xu, Xi Chen, Hongyang Jing, Lixia Wang, Jun Wei, YongdianHan,Design and performance of Ag nanoparticle-modified graphene/SnAgCulead-free solders,Materials Science & Engineering A, 2016, 667: 87~96.

[4]Zhiqiang Zhang, Hongyang Jing,Lianyong Xu*, Yongdian Han, Lei Zhao,Investigation on microstructure evolution and properties of duplex stainlesssteel joint multi-pass welded by using different methods,Materials and Design, 2016, 109: 670~685.

[5] Huayi Li, Hongyang Jing, Yongdian Han, Guo-Quan Lu,Lianyong Xu*, Tun Liu,Interfacial evolution behavior of AgSbTe2.01/nanosilver/Cu thermoelectric joints,Materials and Design, 2016, 89: 604~610.

[6] Yongxin Lu, Hongyang Jing, Yongdian Han, Zhicao Feng,Lianyong Xu*,Recommend design of filler metal to minimize carbon steel weld metal preferential corrosion in CO2-saturated oilfield produced water,Applied Surface Science, 2016, 389: 609~622.

[7]H. Wang, H. Y. Jing, L. Zhao, Y. D. Han,L. Y. Xu*,Study onresidual stress in socket weld by numerical simulation and experiment,Scienceand Technology of Welding and Joining, 2016, 21: 504~514.

[8] Yongxin Lu, Hongyang Jing, Yongdian Han,Lianyong Xu*,Effect oftemperature on the 3Cr low-alloyed steel initial corrosion behavior in CO2solution,Materials Chemistry and Physics, 2016, 178: 160~172.

[9]L.Y Xu, J Zhu, H.Y Jing, L Zhao, X.Q Lv, Y.D Han, Effects of deepcryogenic treatment on the residual stress and mechanical properties ofelectron-beam-welded Ti-6Al-4V joints,Materials Science and Engineering A, 2016, 673: 503~510.

[10]Huayi Li, Hongyang Jing, Yongdian Han, Guo-Quan Lu,Lianyong Xu*,Interface evolution analysis of graded thermoelectric materials joined by low temperature sintering of nano-silver paste,Journal of Alloys and Compounds, 2016, 659: 95~100.

[11]Yuan Li ; Hongyang Jing, Yongdian Han, Guoquan Lu,Lianyong Xu*,Microstructure and Joint Properties of Nano-Silver Paste by Ultrasonic-Assisted Pressureless Sintering,Journal of Electronic Materials, 2016, 45: 3003~3012.

[12]Lianyong Xu, Yongfa Wang,HongyangJing, Lei Zhao, Yongdian Han,Deformation Mechanism and Microstructure Evolution of T92/S30432 DissimilarWelded Joint During Creep,Journal of Materials Engineering and Performance, 2016, 25: 3960~3971.

[13]Yongxin Lu, Hongyang Jing, Yongdian Han,Lianyong Xu*,NumericalModeling of Weld Joint Corrosion,Journal of Materials Engineering andPerformance, 2016, 25: 960~965.

[14]Yongxin Lu, Hongyang Jing, Yongdian Han,Lianyong Xu*,Effect ofWelding Heat Input on the Corrosion Resistance of Carbon Steel Weld Metal,Journal of Materials Engineering and Performance, 2016, 25: 565~576.

2015年

[1]Lei Zhao*,Lianyong Xu*, Yongdian Han, Hongyang Jing,Two-parameter characterization ofconstrainteffect induced by specimen size on creep crack growth,Engineering Fracture Mechanics, 2015, 143: 121~137.

[2]Lei Zhao,LianyongXu*, YongdianHan, HongyangJing,Quantifying theconstraint effect induced by specimen geometry on creep crack growth behaviorin P92 steel,International Journal of Mechanical Sciences, 2015, 94-95: 63~67.

[3] H.Y. Jing, Y.Y. Zhang,L.Y. Xu*, G.S. Zhang, Y.D. Han, J. Wei,Lowcycle fatigue behavior of a eutectic 80Au/20Sn solder alloy,InternationalJournal of Fatigue, 2015, 75: 100~107.

[4] Wen Zhang, Hongyang Jing,Lianyong Xu*, Lei Zhao, Yongdian Han, Congcheng Li,Numerical investigation of creep crack initiation in P92 steelpipes with embedded spherical defects under internal pressure at 650 degrees C,Engineering Fracture Mechanics, 2015, 139: 40~55.

[5]Y.C Xu, H.Y Jing, Y.D Han,L.Y Xu*, Numerical simulation of theeffects of various stud and hole configurations on friction hydro-pillarprocessing,International Journal of Mechanical Sciences, 2015, 90: 44~52.

[6]Lianyong Xu, Lixia Wang, Hongyang Jing, Xiangdong Liu, Jun Wei, Yongdian Han,Effects of graphene nanosheets on interfacial reaction ofSn-Ag-Cu solder joints,Journal of Alloys and Compounds, 2015, 650: 475~481.

[7]L. Y. Xu*, Z. K. Zhang, H. Y. Jing, J. Wei, Y. D. Han,Effect ofgraphene nanosheets on the corrosion behavior of Sn–Ag–Cu solders,Journal ofMaterials Science: Materials in Electronics, 2015, 26: 5625~5634.

[8] Hongyang Jing, Yuan Li,Lianyong Xu*, Yongdian Han, Guoquan Lu, HaoZhang,Interfacial Reaction and Shear Strength of SnAgCu/Ni/Bi2Te3-Based TEMaterials During Aging,Journal of Materials Engineering and Performance, 2015, 24: 4844~4852.

2014年

[1]Lei Zhao, Hongyang Jing, Junjie Xiu, Yongdian Han,Lianyong Xu*,Experimental investigation of specimen size effect on creep crack growth behaviorin P92 steel welded joint,Materials and Design, 2014, 57: 736~743.

[2]L. Y. Xu, Y. F. Wang, H. Y. Jing, Y. D. Han,Fatigue strengthimprovement of stainless steel using weld toes dressing with low transformationtemperature welding wire,Science and Technology of Welding and Joining, 2014,19: 664~672.

[3]Lianyong Xu, Yi Miao, Hongyang Jing, Yongdian Han,Experimentaland Numerical Investigation of Heated Band Width for Local Post Weld HeatTreatment of ASME P92 Steel Pipe,Journal of Pressure Vessel Technology-ASME, 2014, 136: 011401.

[4]L Y Xu, G Y Yang, H Y Jing, J Wei, Y D Han,Ag–graphene hybridconductive ink for writing electronics,Nanotechnology, 2014, 25: 055201.

[5]Lianyong Xu, Hailun Zhao, Hongyang Jing, Yongdian Han,Finite Element Analysis of Calibration Coefficients for Residual Stress Measurements by the Ring Core Procedure,Materials Testing, 2014, 56(11-12): 923-928.（封面文章）

參編著作：

[1]《焊接結(jié)構(gòu)》，第六章“焊接結(jié)構(gòu)高溫力學(xué)性能”，化學(xué)出版社，2012

[2]《中國焊接技術(shù)路線圖》，第九章“焊接力學(xué)與結(jié)構(gòu)制造技術(shù)”，中國科學(xué)技術(shù)出版社，2016

[3]《中國焊接1994-2016》（中英文），第六章“焊接結(jié)構(gòu)”，機(jī)械工業(yè)出版社，2017

[4]《國際焊接學(xué)會（IIW）研究進(jìn)展》，“C-X”專委會和“C-XI”專委會，中國焊接學(xué)會，2018

授權(quán)發(fā)明專利：

[1]Site conditions thick-wall P92 pipe local heat treatment method,美國，US9663841B2

[2]超小型微創(chuàng)高溫蠕變疲勞試驗(yàn)機(jī)及其應(yīng)用，中國，ZL2012100863064

[3]現(xiàn)場工況厚壁P92管道局部熱處理方法，中國，ZL2012100847502

[4]能夠使不銹鋼焊接接頭焊趾處產(chǎn)生壓縮殘余應(yīng)力的藥芯焊絲，中國，ZL2011100263747

[5]一種錫基銀石墨烯無鉛復(fù)合釬料的制備方法，中國，ZL2015106245825

[6]石墨烯增強(qiáng)無鉛釬料及其制備方法，中國，ZL2012100807134

[7]深冷處理在消除鈦合金電子束焊接殘余應(yīng)力中的應(yīng)用，中國，ZL2013103979777

[8]一種用于材料性能測試的導(dǎo)向彎曲裝置，中國，ZL2013103201737

[9]一種采用超聲輔助納米銀焊膏燒結(jié)制作功率模塊的方法，中國，ZL2014104252035

[10]一種管子環(huán)焊縫試樣蠕變試驗(yàn)裝置，中國，ZL2014104520594

[11]大功率芯片連接的低溫?zé)�結(jié)方法及納米銀焊膏厚度控制裝置，中國，ZL2009100694416

[12]混合動力汽車雙面冷卻平面高溫逆變器，中國，ZL2009100694401

[13]一次性燒結(jié)多個不同厚度芯片的裝置，中國，ZL2011103459449

[14]一種液相法制備石墨烯/銀納米粒子復(fù)合材料的方法，中國，ZL2012100549522

[15]基于納米銀焊膏連接芯片的陶瓷-銅鍵合基板表面處理工藝，中國，ZL2012100233356

等23件

本課題組擁有雄厚的科研基礎(chǔ)、一流的研究平臺和優(yōu)厚的獎助學(xué)金體系，歡迎有志于科技創(chuàng)新、勤奮嚴(yán)謹(jǐn)、踏實(shí)肯干的材料成型及控制、金屬材料、力學(xué)、機(jī)械等專業(yè)同學(xué)報考！

主頁：https://mse.tju.edu.cn/info/1143/1534.htm