唐帅副教授简介

发布人:Super User  发布时间:2011-11-02  浏览次数:7947

唐帅副教授


 

 

 

教师姓名:

唐帅

办公地点:

RAL214

办公电话:

024-83686419

传    真:

024-23906472

电子邮件:

职    称:

副教授

研究方向:

①低成本高性能钢铁材料制备理论与工艺;
②先进金属材料制备技术及理论;
③金属制品表面质量控制及其机理研究

通讯地址:

辽宁省沈阳市东北大学(南湖)105#

邮政编码:

110819

 


 

一、个人简历

受教育经历:

2004.09-2011.01 东北大学 材料加工工程 硕-博连读
2000.09-2004.07 东北大学 冶金工程 本科

 

研究工作经历:

2014.01- 今 东北大学 副教授
2017.12-2018.12 荷兰代尔夫特理工大学(TU Delft) 访问学者
2010.12-2013.12 东北大学 讲师

 

 

二、教学情况(本科生/研究生)

  

控制轧制与控制冷却 本科生
课程设计 本科生

 

三、主要研究项目

[1]. 国家自然科学基金面上项目—基于第一性原理的相间析出强化型高强度高局部成形性能多相钢的组织性能控制,负责人,项目编号:51774083
[2]. 教育部项目基本科研业务费项目国家项目培育种子基金—复合纳米析出强化型高强度高局部成形性相变诱导塑性钢的组织性能控制机理,负责人,项目编号:N150704001
[3] 国家自然科学基金青年项目—超快冷条件下铁素体相变与协同相间析出的控制机理,负责人,项目编号:51204049
[4]. 教育部项目基本科研业务费项目—超快冷条件下的铁素体相变及纳米级相间析出的控制机理研究,负责人,项目编号:N110307002
[5]. 上海梅山钢铁股份有限公司-低成本V微合金化高强钢工艺开发, 负责人,项目编号:2017040200100
[6]. 建筑用经济型高可焊性中高强度结构钢的开发与应用:I 材料研发与应用性能研究, 负责人,项目编号:2017040200046
[7]. 上海梅山钢铁股份有限公司-以新一代TMCP技术为特征的节约型热轧低碳微合金工艺开发,负责人,项目编号:2015-0-1-07405
[8]. 国家自然科学基金重点项目—超快速冷却条件下低碳钢中纳米碳化物析出控制及综合强化机理,参与人,项目编号:51234002
[9]. 国家自然科学基金面上项目—不锈钢低熔点元素微合金化机理与偏析行为控制技术,参与人,项目编号:51271050
[10]. 国家科技支撑计划子课题—热轧板带钢新一代TMCP装备及工艺技术开发与应用,参与人,项目编号:2012BAF04B00
[11]. 国家高技术研究发展计划(863 计划) —海洋石油平台用高强度、厚规格钢板生产的关键技术及原理,参与人,项目编号:2007AA03Z504
负责梅钢、鞍钢、首钢等横向项目3项,参与横向项目8项。

 

 四、代表性成果(论文/专著/专利/获奖等)

 

论文情况:


1. Xin-Jun Shen, Shuai Tang*, Jun Chen, Zhen-Yu Liu, R.D.K. Misra, Guo-Dong Wang. Grain Refinement in Surface Layers through Deformation-induced Ferrite Transformation in Microalloyed Steel Plate[J]. Materials & Design, 2017, 113: 137-141.
2. Xin-Jun Shen, Shuai Tang*, Jun Chen, Zhen-Yu Liu, Guo-Dong Wang. Improving Toughness of Heavy Steel Plate by Deformation Distribution Under Low Finish Cooling Temperature[J]. Journal of Materials Engineering and Performance, 2016, 25(9): 3682-3690.
3. Xin-Jun Shen, Shuai Tang*, Jun Chen, Zhen-Yu Liu, R.D.K. Misra , Guo-Dong Wang. The Effect of Warm Deforming and Reversal Austenization on the Microstructure and Mechanical Properties of a Microalloyed Steel[J]. Material Science and Engineering A, 2016, 671: 182-189.
4. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Coupled toughening of a low carbon medium manganese heavy steel plate investigated by electron back-scattered diffraction (EBSD)[J]. Materials Letters, 2016, 175: 203-206.
5. Feng-Qin Ji*, Cheng-Ning Li, Shuai Tang, Guo Yuan, Guo-Dong Wang. Microstructural Characteristics with various finish rolling temperature and low temperature toughness in hot rolled Nb-Ti ferritic steel[J]. ISIJ International, 2016, 56(4): 602-609.
6. Xin-Jun Shen, Shuai Tang*, Xiao-Long Yang, Guo-Dong Wang. Simulation of hot rolling texture under plane strain condition by thermo-mechanical simulator[J]. Dongbei Daxue Xuebao/Journal of Northeastern University, 2016, 37(8): 1104-1107 (in Chinese).
7. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Correlation between mechanical properties and retained austenite characteristics in a low-carbon medium manganese alloyed steel plate[J]. Materials Characterization, 2015, 106: 108-111.
8. Xin-Jun Shen, Shuai Tang*, Jun Chen, Zhen-Yu Liu, Guo-Dong Wang. Formation of fine austenite through static recrystallization in low carbon micro-Alloyed steels[J]. ISIJ International, 2015, 55(12): 2657-2660.
9. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Influence of Thermomechanical Control Process on the Evolution of Austenite Grain Size in a Low-Carbon Nb-Ti-Bearing Bainitic Steel[J]. Journal of Materials Engineering and Performance, 2015, 24(10): 3852-3861.
10. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Low-carbon bainite steel with high strength and toughness processed by recrystallization controlled rolling and ultra fast cooling (RCR+UFC)[J]. ISIJ International, 2014, 54(12): 2926-2932.
11. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Influence of cooling paths on microstructural characteristics and precipitation behaviors in a low carbon V-Ti microalloyed steel[J]. Materials Science and Engineering A, 2014, 594: 389-393.
12. Xin-Jun Shen, Xiang-Jun Zhang, Feng-Qin Ji, Jun Chen, Shuai Tang*, Guo-Dong Wang. Effects of processing parameters on the evolution of microstructure and hole expansion property of F/B dual phase steels[C]. Materials Science Forum, 2014, 788: 384-389.
13. Jun Chen, Shuai Tang*, Zhen-Yu Liu, Guo-Dong Wang. Dynamic recrystallization behaviors of high performance bridge steels with lower Ni, Cr, Cu and Mo contents[J]. Dongbei Daxue Xuebao/Journal of Northeastern University, 2014, 35(7): 960-963+968 (in Chinese).
14. Zhuang-Fei Wang*, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Effect of Nb on continuous cooling transformation behavior of low carbon microalloyed steel[J]. Dongbei Daxue Xuebao/Journal of Northeastern University, 2014, 35(8): 1117-1119 (in Chinese).
15. Xin-Jun Shen, Xin-Hua Pei, Shuai Tang*, Guo-Dong Wang. Effects of coiling temperature on microstructure and mechanical properties of hot-rolled ferrite/bainite dual phase steel[J]. Dongbei Daxue Xuebao/Journal of Northeastern University, 2014, 35(8): 1120-1123 (in Chinese).
16. Jun Chen*, Meng-Yang Lv, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Microstructure, mechanical properties and interphase precipitation behaviors in V-Ti microalloyed steel[J]. Jinshu Xuebao/Acta Metallurgica Sinica, 2014, 50(5): 524-530. (in Chinese).
17. Shuai Tang*, Zhen-Yu Liu, Gong-Dong Wang, R.D.K. Misra. Microstructural evolution and mechanical properties of high strength microalloyed steels: Ultra Fast Cooling (UFC) versus Accelerated Cooling (ACC)[J]. Material Science and Engineering A, 2013, 580, 257-265.
18. Jun Chen*, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Influence of molybdenum content on transformation behavior of high performance bridge steel during continuous cooling[J]. Materials and Design, 2013, 49: 465-470.
19. Jun Chen*, Xiang-Wei Chen, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Effect of cooling paths on microstructure and mechanical properties of vanadium bearing microalloyed steel[C]. Materials Science Forum, 2013, 749: 243-249.
20. Jun Chen*, Li Fan, Zhen-Yu Liu, Shuai Tang, Guo-Dong. Wang Influence of deformation temperature on γ−α phase transformation in Nb-Ti microalloyed steel during continuous cooling[J]. ISIJ International, 2013, 53(6): 1070-1075.
21. Jun Chen*, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang Microstructural characteristics with various cooling paths and the mechanism of embrittlement and toughening in low-carbon high performance bridge steel[J]. Materials Science and Engineering A, 2013, 559: 241-249.
22. Feng-Qin Ji, Cheng-Ning Li, Jun Chen, Shuai Tang. Guo-Dong Wang. Effects of carbon and niobium on microstructure and mechanical properties of high strength stee[C]. Materials Science and Technology Conference and Exhibition, 2013, 1: 369-374.
23. Jun Chen*, Shuai Tang, Zhen-Yu Liu, Guo-Dong Wang. Effects of UFC final cooling temperature on microstructure and mechanical properties of bridge steels[J]. Dongbei Daxue Xuebao/Journal of Northeastern University, 2013, 34(4):524-527 (in Chinese).
24. Zhen-Yu Liu*, Shuai Tang, Xiao-hui Cai, Guo-Dong Wang. Precipitation strengthening of micro-alloyed steels thermo-mechanically processed by ultra fast cooling[C]. Materials Science Forum, 2012, 706-709: 2320-2325.
25. Jun Chen, Shuai Tang*, Yan-Lei Zhou, Zhen-Yu Liu, Guo-Dong Wang, Ying Yang, Jun-Ping Chen. Dynamic recrystallization behaviors of low carbon Q690qENH high-strength bridge steels[J]. Cailiao Yanjiu Xuebao/ Chinese Journal of Materials Research, 2012, 26(2): 199-205 (in Chinese).
26. Jun Chen, Shuai Tang, Zhen-Yu Liu*, Guo-Dong Wang, Yan-Lei Zhou. Strain-induced precipitation kinetics of Nb (C, N) and precipitates evolution in austenite of Nb-Ti micro-alloyed steels[J]. Journal of Materials Science, 2012, 47(11): 4640-4648.
27. Yong Tian*, Shuai Tang, Guo-Dong Wang, Pu Wang. Industrial trial production of X70 pipeline steel under ultra fast cooling conditions[C]. Applied Mechanics and Materials, 2012, 121-126: 3340-3344.
28. Tian Yong*, Shuai Tang, Bing-Xing Wang, Zhao-Dong Wang, Guo-Dong Wang. Development and industrial application of ultra-fast cooling technology[J]. Science China Technological Sciences, 2012, 55(6): 1566-1571.
29. Jun Chen, Shuai Tang*, Zhen-Yu Liu, Guo-Dong Wang. Effects of cooling process on microstructure, mechanical properties and precipitation behaviors of niobium-titanium micro-alloyed steel[J]. Jinshu Xuebao/Acta Metallurgica Sinica, 2012, 48(4): 441-449 (in Chinese).
30. Jun Chen, Shuai Tang*, Yan-Lei Zhou, Zhen-Yu Liu, Guo-Dong Wang, Ying Yang, Jun-Ping Chen. Dynamic recrystallization behaviors of low carbon Q690qENH high-strength bridge steels[J]. Cailiao Yanjiu Xuebao/ Chinese Journal of Materials Research, 2012, 26(2): 199-205 (in Chinese).
31. Shuai Tang, Zhen-Yu Liu*, Guo-Dong Wang, Development of High Strength Plates with Low Yield Ratio by the Combination of TMCP and Inter-Critical Quenching and Tempering[J]. Steel Research International, 2011, 82(7): 772-778.
32. Shuai Tang, Zhen-Yu Liu*, Guo-Dong Wang, Yuan-chun He. Present situation and development tendency of steel plates for high-rise constructional steel[J], Journal of iron and steel research. 2010, 22(10): 1-6,7(in Chinese).
33. Shuai Tang*, Zhen-Yu Liu, Guo-Dong Wang. Study on DL-T technology of low yield ratio 590/780Mpa steels for construction [J], Steel Rolling, 2010, 27(1): 6-10(in Chinese).

 

专利情况:

[1]. 一种止裂性能优异的厚钢板及其制造方法, ZL 201510109864.1,唐帅;刘振宇;沈鑫珺;陈俊;张向军;王国栋;2017年03月15日授权
[2]. 一种590MPa级低屈强比低碳当量建筑用钢板的制造方法,ZL 200810011049.1,刘振宇;唐帅;孙庆强;刘相华;王国栋;2010年01月06日授权
[3]. 中薄板坯连铸连轧带钢表面氧化铁皮控制方法,ZL 200710010183.5,于洋;郭晓波;钟莉莉;关菊;刘振宇;唐帅;2008年12月17日授权

 

科研获奖:

[1]. 节约型高性能中厚板UFC-TMCP工艺技术开发及应用,辽宁省科学技术进步奖,一等奖,总排名第4,校内第2,第4,2015辽宁省科学技术奖励委员会
[2]. 首钢4300mm宽厚板生产线超快速冷却系统开发及新一代TMCP工艺的应用,北京市科技进步奖,一等奖,总排名第8,校内第4,2012,北京市科学技术奖励工作办公室
[3]. 热轧钢材氧化铁皮关键控制技术创新与推广应用,教育部科技进步奖(推广类),二等奖,总排名第11,校内第4,2013,教育部
[4] 基于超快冷工艺条件下Nb在钢铁材料中物理冶金规律的研究与生产工艺开发,中信铌钢技术进步奖,三等奖,总排名第4,校内第4,2013,中信金属有限公司中信微合金化技术中心
[5] 鞍钢连铸连轧工艺氧化铁皮控制技术,冶金科学技术奖,一等奖,总排名第8,校内第4,2008,中国钢铁工业协会中国金属学会冶金科学技术奖奖励委员会