唐帥

2004.09-2011.01 東北大學 材料加工工程 碩-博連讀

2000.09-2004.07 東北大學 冶金工程 本科 ^[1] 

2014.01- 今 東北大學 副教授

2017.12-2018.12 荷蘭代爾夫特理工大學（TU Delft） 訪問學者

2010.12-2013.12 東北大學 講師 ^[1] 

控制軋製與控制冷卻 本科生

課程設計 本科生 ^[1] 

①低成本高性能鋼鐵材料製備理論與工藝；

②先進金屬材料製備技術及理論；

③金屬製品表面質量控制及其機理研究 ^[1] 

[1]. 國家自然科學基金面上項目—基於第一性原理的相間析出強化型高強度高局部成形性能多相鋼的組織性能控制，負責人，項目編號：51774083

[2]. 教育部項目基本科研業務費項目國家項目培育種子基金—複合納米析出強化型高強度高局部成形性相變誘導塑性鋼的組織性能控制機理，負責人，項目編號：N150704001

[3] 國家自然科學基金青年項目—超快冷條件下鐵素體相變與協同相間析出的控制機理，負責人，項目編號：51204049

[4]. 教育部項目基本科研業務費項目—超快冷條件下的鐵素體相變及納米級相間析出的控制機理研究，負責人，項目編號：N110307002

[5]. 上海梅山鋼鐵股份有限公司-低成本V微合金化高強鋼工藝開發, 負責人，項目編號：2017040200100

[6]. 建築用經濟型高可焊性中高強度結構鋼的開發與應用：I 材料研發與應用性能研究, 負責人，項目編號：2017040200046

[7]. 上海梅山鋼鐵股份有限公司-以新一代TMCP技術為特徵的節約型熱軋低碳微合金工藝開發，負責人，項目編號：2015-0-1-07405

[8]. 國家自然科學基金重點項目—超快速冷卻條件下低碳鋼中納米碳化物析出控制及綜合強化機理，參與人，項目編號：51234002

[9]. 國家自然科學基金面上項目—不鏽鋼低熔點元素微合金化機理與偏析行為控制技術，參與人，項目編號：51271050

[10]. 國家科技支撐計劃子課題—熱軋板帶鋼新一代TMCP裝備及工藝技術開發與應用，參與人，項目編號：2012BAF04B00

[11]. 國家高技術研究發展計劃(863 計劃) —海洋石油平台用高強度、厚規格鋼板生產的關鍵技術及原理，參與人，項目編號：2007AA03Z504

負責梅鋼、鞍鋼、首鋼等橫向項目3項，參與橫向項目8項。 ^[1] 

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). ^[1] 

[1]. 一種止裂性能優異的厚鋼板及其製造方法, ZL 201510109864.1，唐帥；劉振宇；沈鑫珺；陳俊；張向軍；王國棟;2017年03月15日授權

[2]. 一種590MPa級低屈強比低碳當量建築用鋼板的製造方法，ZL 200810011049.1，劉振宇;唐帥;孫慶強;劉相華;王國棟;2010年01月06日授權

[3]. 中薄板坯連鑄連軋帶鋼表面氧化鐵皮控制方法，ZL 200710010183.5,於洋;郭曉波;鍾莉莉;關菊;劉振宇;唐帥;2008年12月17日授權 ^[1] 

[1]. 節約型高性能中厚板UFC-TMCP工藝技術開發及應用，遼寧省科學技術進步獎，一等獎，總排名第4，校內第2，第4，2015遼寧省科學技術獎勵委員會

[2]. 首鋼4300mm寬厚板生產線超快速冷卻系統開發及新一代TMCP工藝的應用，北京市科技進步獎，一等獎，總排名第8，校內第4，2012，北京市科學技術獎勵工作辦公室

[3]. 熱軋鋼材氧化鐵皮關鍵控制技術創新與推廣應用，教育部科技進步獎（推廣類），二等獎，總排名第11，校內第4，2013，教育部

[4] 基於超快冷工藝條件下Nb在鋼鐵材料中物理冶金規律的研究與生產工藝開發,中信鈮鋼技術進步獎,三等獎,總排名第4，校內第4，2013，中信金屬有限公司中信微合金化技術中心

[5] 鞍鋼連鑄連軋工藝氧化鐵皮控制技術，冶金科學技術獎，一等獎，總排名第8，校內第4，2008，中國鋼鐵工業協會中國金屬學會冶金科學技術獎獎勵委員會 ^[1]