李花兵

作者:发布时间:2019-08-19浏览次数:9400

李花兵

出生年月

1978.05

政治面貌

中共党员

教授、博导

副所长,辽宁省特种钢冶炼重点实验室副主任

办公电话

024-83689580

电子邮箱

lihb@smm.neu.edu.cnhuabing_li@163.com

学习经历:

1998.09 - 2002.07 攻读东北大学冶金科学与工程专业学士学位;

2002.09 - 2004.07 攻读东北大学钢铁冶金专业硕士学位;

2004.03 - 2008.03 攻读东北大学钢铁冶金专业博士学位。

工作经历:

2005.03 - 2008.02,东北大学材料与冶金学院,钢铁冶金研究所,助教;

2008.03 - 2009.12,东北大学材料与冶金学院,钢铁冶金研究所,讲师;

2010.01 - 2016.12东北大学材料与冶金学院,钢铁冶金研究所,副教授;

2012.07 - 2016.12,山西太钢不锈钢股份有限公司,在职博士后;

2017.01 - 至今,东北大学冶金学院,特殊钢冶金研究所,教授;

2018.01 - 至今,东北大学冶金学院,特殊钢冶金研究所,长聘教授;

2018.07 - 至今,东北大学冶金学院,特殊钢冶金研究所,博士生导师。

主要研究方向:

1)高品质特殊钢冶金理论及新工艺开发;

2)高氮不锈钢加压冶金理论、制备技术及新品种开发;

3)高性能不锈钢冶炼工艺及新品种开发。

近年讲授课程:特殊钢材料学及冶金原理、《直读光谱分析》、《腐蚀电化学原理及测试技术》、《感应炉炼钢》等课程

所在团队情况:特殊钢冶金研究所(姜周华教授团队)

人才培养情况:

1)培养和协助培养本科生28人(独立指导18人);培养和协助培养硕士研究生63人(独立指导40);培养和协助培养博士研究生23人(独立指导15人);

2指导学生在首届中国金属学会冶金青年创新创意大赛等科技创新/创业大赛中获奖5 项(全国特等奖1项,二等奖2项,三等奖1项;省特等奖1项)。

科研项目情况:

长期致力于高品质特殊钢冶炼工艺及新品种开发方面的教学和科研工作,主持重点基金,重点研发计划(战略科技创新)、重点研发计划子课题、863子课题,国家自然基金面上等项目40余项,经费累计2000余万元。围绕高品质高氮不锈钢制备技术及品种开发,突破了常压下高纯净护环钢(氮含量0.65%以上)工业化稳定生产的技术瓶颈,实现了600MW以上大容量超超临界火电和核电机组用护环国产化,打破了德国和日本30多年技术封锁和市场垄断;首次研发了加压冶炼关键装备,攻克了加压冶金制备关键技术;阐明了氮在冶炼、凝固和材料中的行为,明晰了加压强化冷却和改善凝固组织机理,丰富和发展了加压冶金理论,研发了新一代航空高氮不锈轴承钢等系列高氮不锈钢新品种。围绕高性能不锈钢,突破了资源节约型、热核聚变实验堆用和超级等系列不锈钢制备关键科学和技术难题,实现批量稳定化生产,实物质量达到国际先进水平,满足了我国高端装备制造业材料急需。

代表性项目:

1)重点研发计划(战略科技创新),2021YFE0204100,航空关键材料基因工程与人工智能设计,2020/08-2022/07188万元,主持;

2)国家自然科学基金钢铁联合基金重点项目,U1960203,基于加压感应和加压电渣双联工艺制备高性能航空高氮不锈轴承钢的基础研究,2020/01-2023/12320万元,主持;

3)国家自然科学基金面上项目,51774074,基于氮气压力动态调节的电渣重熔制备高氮高速钢梯度材料的基础研究,2018/1-2021/1260万元,主持;

4)国家自然科学基金青年项目,51304041,气相渗氮和微弧增氮的加压电渣重熔技术制备含氮耐蚀塑料模具钢的基础研究,2014/01-2016/1225万元,主持;

5)辽宁省“兴辽英才计划”项目,XLYC1902046,加压双联工艺制备高性能航空高氮不锈轴承钢的基础研究,2020/01-2022/12100万元,主持;

6)十三五重大研发计划子课题,2016YFB0300203620℃超超临界火电机组汽轮机用耐热不锈钢转子研制,2016/1-2019/1290万元,主持;

7863计划子课题,2015AA034301,典型极端环境下超级不锈钢服役行为及其制备技术,2015/04-2018/03140万元,主持;

8863计划子课题,2012AA03A502,开发600MW以上大容量超超临界火电机组汽轮机护环,2012/05-2015/12265万元,主持;

9)国家自然科学基金重点项目,51434004,高品质特殊钢加压下熔炼和凝固的基础研究,2015/01-2019/12340万元,骨干(第二,执行负责);

10)联合基金重点项目(军民共用重大研究计划),U1435205,高品质特殊钢加压下熔炼和凝固的基础研究,2015/01-2018/12160万元,骨干(第二,执行负责);

11)国家自然科学基金联合资助重点项目,50534010,高氮不锈钢中氮的作用机理及对性能的影响,2006/01-2009/12170万元,骨干(执行负责)。

论文著作情况:

近五年,发表SCI论文100余篇,其中以一作和通讯发表80余篇(Corros. Sci.J. Mater. Sci. Technol.Metall. Mater. Trans. BISIJ Int.Steel Res. Int.Mater. Sci. Eng., AMetall. Mater. Trans. AJ. Alloys Compd.Mater. Charact.Mater. Des等期刊);主编《高氮不锈钢》专著1部,参编专著《炼钢过程中的夹杂物》和《中国不锈钢》等5部;授权发明专利40余项(美专1项)。

代表性论著:

1X.J. Li, P.   Zhou, H. Feng, Z.H. Jiang, H.B. Li*, et al. Spontaneous passivation of   the CoCrFeMnNi high entropy alloy in sulfuric acid solution: The effects of   alloyed nitrogen and dissolved oxygen, Corrosion Science, 2022,   196: 110016.

2J.T. Yu, S.C.   Zhang, H.B. Li*, et al. Influence mechanism of boron segregation on   the microstructure evolution and hot ductility of super austenitic stainless   steel S32654, Journal of Materials Science & Technology,   2022, 112:184–194.

3S.C. Zhang,   J.T. Yu, H.B. Li*, et al. Refinement mechanism of cerium addition on   solidification structure and sigma phase of super austenitic stainless steel   S32654, Journal of Materials Science & Technology, 2022,   102: 105–114.

4X.L. Liu, H.   Feng, J. Wang, X.F. Chen, P. Jiang, F.P. Yuan, H.B. Li*, et al.   Mechanism of dislocation evolution during plastic deformation of   nitrogen-doped CoCrFeMnNi high-entropy alloy, Journal of Materials   Science & Technology, 2022, 108: 256–269.

5J.L. Tian,   K. Chen, H.B. Li*, et al. Suppressing grain boundary embrittlement via   Mo-driven interphase precipitation mechanism in martensitic stainless steel, Materials   Science & Engineering A, 2022, 833: 142529.

6P.C. Lu, H.B.   Li*, H. Feng, et al. Formation Mechanism of AlN Inclusion in   High-Nitrogen Stainless Bearing Steels, Metallurgical and Materials   Transactions B, 52, 2210-2223 (2021).

7H.C. Zhu, H.B.   Li*, Z.Y. He, et al. Effect of Solidification Pressure on Gap Width   between H13 Ingot and Mold, Metallurgical and Materials Transactions B,   52, 2210-2223(2021).

8H. Feng, H.B.   Li*, Z.Z. Liu, et al. Cleanliness Control of High Nitrogen Stainless   Bearing Steel by Vacuum Carbon Deoxidation in a PVIM Furnace, Metallurgical   and Materials Transactions B, 52, 3777-3787 (2021).

9S.X. Yang, H.B.   Li*, H. Feng, et al. Desulfurization Behavior 1 of Fe−18Cr−18Mn Alloy   during the Pressurized Electroslag Remelting with Different Atmospheres and   Na2O-containing Slags, Metallurgical and Materials   Transactions B., 52, 1294-1308(2021).

10H.C. Zhu, H.B.   Li*, Z.W. Ni, et al. Effect of Solidification Pressure on Phase   Transformation and Precipitated Phases of 30Cr15Mo1N Ingot, Metallurgical   and Materials Transactions B, 2021, online.

11H. Feng, P.C.   Lu, H.B. Li*, et al. Effect of Mg Pretreatment and Ce Addition on   Cleanliness and Inclusion Evolution in High-Nitrogen Stainless Bearing   Steels, Metallurgical and Materials Transactions B, 2021,   accepted.

12W.C. Jiao, H.B.   Li*, H. Feng, et al. Significant Improvement of Cleanliness and Macro   micro-structure of As-cast AISI M42 High Speed Steel by Mg Treatment, Metallurgical   and Materials Transactions B, 2021, accepted.

13S.X. Yang, H.B.   Li*, H. Feng, et al. Reaction Mechanism and Control Strategy of Aluminum   Increase in High Nitrogen Stainless Bearing Steel during Pressurized   Electroslag Remelting, Metallurgical and Materials Transactions B,   2021, accepted.

14S.X. Yang, H.   Feng, H.B. Li*, et al. Nitrogen Solubility in Liquid Fe–Nb, Fe–Cr–Nb,   Fe–Ni–Nb and Fe–Cr–Ni–Nb Alloys, ISIJ International, 61(2021):   5, 1498-1505.

15H.C. Zhu, H.B.   Li*, et al. Effect of Pressure on Dendrite Structure and Characteristics   of Carbides during Solidification Process of H13 Die Steel Ingot, ISIJ   International, 61(2021): 6, 1889-1898.

16L.C. Zheng, H.B.   Li*, et al. Effect of CaF2 on Viscosity and Refining Ability   of Highly Basic Slags for Duplex Stainless Steel, ISIJ International,   61(2021): 6, 1784-1793.

17K. Chen, H.B.   Li*, Z.H. Jiang, et al. Multiphase   microstructure formation and its effect on fracture behavior of medium carbon   high silicon high strength steel, Journal of Materials Science &   Technology, 72 (2021) 81–92.

18Y. Han, H.B.   Li*, H. Feng, et   al. Simultaneous enhancement in strength and ductility of Fe50Mn30Co10Cr10   high-entropy alloy via nitrogen alloying, Journal of Materials Science   & Technology, 65 (2021) 210–215.

19J.L. Tian,   W. Wang, H.B. Li*, et al. Understanding main factors controlling high   cycle fatigue crack initiation and propagation of high strength maraging   stainless steels with Ti addition, Materials Science & Engineering   A, 805 (2021) 140589.

20S.C. Zhang, H.B.   Li*, Z.H. Jiang, et al. Influence of N on precipitation behavior,   associated corrosion and mechanical properties of super austenitic stainless   steel S32654, Journal of Materials Science & Technology, 2020,42,   143-155.

21S.C. Zhang, H.B.   Li*, Z.H. Jiang, et al. Chloride- and sulphate-induced hot corrosion   mechanism of super austenitic stainless steel S31254 under dry gas   environment, Corrosion Science, 2020,163, 108295.

22J. Dai, H.   Feng, H.B. Li*, et al. Nitrogen significantly enhances corrosion   resistance of 316L stainless steel in thiosulfate-chloride solution, Corrosion   Science, 2020, 174, 108792.

23W.C. Jiao, H.B.   Li*, H. Feng, et al. Evolutions of Micro- and Macrostructure by Cerium   Treatment in As-Cast AISI M42 High-Speed Steel, Metallurgical and   Materials Transactions B, 51, 2240–2251(2020).

24H.C. Zhu, H.B. Li*, Z.Y. He, et al. Effect of   Pressure on Inclusion Number Distribution During the Solidification Process   of H13 Die Steel, Metallurgical and Materials Transactions B, 51,   2976–2992(2020).

25W.C. Jiao, H.B. Li*,H. Feng, et al. Effect of High Nitrogen Addition   on Microstructure and Mechanical Properties of As-cast M42 High Speed Steel, ISIJ   International, 60 (2020), 564–572.

26C.Y. Chen, Z.H.   Jiang, Y. Li, M. Sun, Q. Wang, K. Chen and H.B. Li*. State of   the Art in the Control of Inclusions in Spring Steel for Automobile - a   Review, ISIJ International, 60 (2020), 617–627.

27J. Yu, F.B.   Liu, Z.H. Jiang, H.B. Li*, et al. Effects of Nitrogen   Gas Pressure on the Solidification Parameters and As-cast Microstructure   Revolution during Pressurized Electroslag Remelting AISI 304 Stainless Steel,   ISIJ International, 60 (2020),1684–1692.

28H.C. Zhu, H.B. Li*, Z.H. Jiang, et al. Quantitative Correlation between   Interfacial Heat Transfer Coefficient and Pressure for 19Cr-14Mn-0.9N High   Nitrogen Steel Cylindrical Ingot, ISIJ International, 60   (2020), 1978–1984.

29Y. Han, H.B. Li*, H. Feng, et al. Enhancing the strength and ductility of   CoCrFeMnNi high-entropy alloy by nitrogen addition, Materials Science   & Engineering A, 789 (2020) 139587.

30K. Chen, Z.H.   Jiang*, F.B. Liu, H.B. Li*, et al. Enhanced mechanical   properties by retained austenite in medium–carbon Si-rich microalloyed steel   treated by quenching–tempering, austempering and austempering–tempering   processes, Materials Science & Engineering A, 790 (2020)   139742.

31K. Chen, Z.H.   Jiang, F.B. Liu, H.B. Li*, et al. Achievement of High   Ductility and Ultra-high Strength of V-Nb Microalloyed Spring Steel by   Austempered Multiphase Microstructure, Metallurgical and Materials   Transactions A, 51, 3565–3575(2020).

32H. Feng, H.B. Li*, Z.H. Jiang, et al. Designing for high corrosion-resistant   high nitrogen martensitic stainless steel based on DFT calculation and   pressurized metallurgy method. Corrosion Science, 2019, 158   (2019) 108081.

33H. Feng, H.B. Li*, W.C. Jiao, et al. Significance of Partial Substitution of   C by N on Strengthening and Toughening Mechanisms of High Nitrogen   Fe-15Cr-1Mo-C-N Martensitic Stainless Steels. Metallurgical and Materials   Transactions A, 2019, 50(11): 4987–4999.

34W.C. Jiao, H.B. Li*, J. Dai, et al. Effect of partial replacement of carbon by   nitrogen on intergranular corrosion behavior of high nitrogen martensitic   stainless steels. Journal of Materials Science & Technology,2019, 35 (2019) 2357–2364.

35J. Yu, F.B.   Liu, H.B. Li*, et al. Numerical Simulation and Experimental   Investigation of Nitrogen Transfer Mechanism from Gas to Liquid Steel During   Pressurized Electroslag Remelting Process. Metallurgical and Materials   Transactions B, 2019, 50, 3112~3124.

36J. Yu, F.B.   Liu, H.B. Li*, et al. Effects of mold current on slag skin and heat flow   distribution during electroslag remelting at given power input. JOM,   71 (2019)744-753.

37Z.H. Jiang,   G. Xu, Yang Li, H.B. Li*, et al. Effect of Ultra-high   Magnesium on SKS51 Liquid Steel Cleanliness and Microstructure. ISIJ   International, 59 (2019) 1234-1241.

38H. Feng, Z.H.   Jiang, H.B. Li*, et al. Influence of nitrogen on corrosion behaviour of   high nitrogen martensitic stainless steels manufactured by pressurized   metallurgy. Corrosion Science, 144 (2018) 288-300.

39H. Feng, H.B. Li*, X.L. Wu, et al.Effect of nitrogen on corrosion behaviour   of a novel high nitrogen medium-entropy alloy CrCoNiN manufactured by   pressurized metallurgy. Journal of Materials Science &   Technology, 2018, 34: 1781–1790.

40Z.H. Jiang,   H.C. Zhu, H.B. Li*, et al. A Novel   Method for Improving Cast Structure of M42 High Speed Steel by Pressurized   Metallurgy Technology, ISIJ International, 2018, 58 (7):   1267–1274.

41Z.H. Jiang,   H.C. Zhu, H.B. Li*, et al. Effect   of solidification pressure on interfacial heat transfer and solidification   structure of 19Cr14Mn0.9N high nitrogen steel, ISIJ International,   2018, 58 (1): 107–113.

42Y. Li, C.Y.   Chen, Z.H. Jiang, M. Sun, H. Hu and H.B.   Li*. Application of Alkali   Oxides in LF Refining Slag for Enhancing Inclusion Removal in C96V Saw Wire   Steel, ISIJ International, 2018, 58 (7): 1232–1241.

43C.Y. Chen, Z.H.   Jiang, Y. Li, M. Sun, G.Q. Qin, C.L. Yao, Q. Wang and H.B. Li*. Effect   of Rb2O on Inclusion Removal in C96V Saw Wire Steels Using Low-Basicity LF   Refining Slag, ISIJ International, 2018, 58 (2018) 2032-2041.

44H.C. Zhu,   Z.H. Jiang, H.B. Li*. Effect of   Solidification Pressure on Thermodynamic and Kinetic Parameters of   19Cr14Mn4Mo0.9N High Nitrogen Steel. Steel Research International,   2018, 89(5): 1700475.

45H.C. Zhu,   Z.H. Jiang*, H. B. Li*, et al.   Effects of nitrogen segregation and solubility on the formation of nitrogen   gas pores in 21.5Cr-1.5Ni duplex stainless steel, Metallurgical and Materials   Transactions B, 2017, 48, 2493-2503.

46H.B. Li*,   S.X. Yang, S.C. Zhang*, et al. Microstructure evolution and mechanical   properties of friction stir welding super-austenitic stainless steel S32654, Materials and Design,   2017, 118:207-217.

47H.B. Li, C.T. Yang,   E.Z. Zhou, C.G. Yang*, et al. Microbiologically influenced corrosion behavior   of S32654 super austenitic stainless steel in the presence of marine   pseudomonas aeruginosa biofilm, Journal of Materials Science & Technology,   2017, 1-8.

48S.C. Zhang,   Z.H. Jiang, H.B. Li*, et al.   Detection of susceptibility to intergranular corrosion of aged super   austenitic stainless steel S32654 by a modified electrochemical   potentiokinetic reactivation method, Journal of Alloys and Compounds,   2017, 695: 3083~3093.

49H.C. Zhu,   Z.H. Jiang, H.B. Li*, J.H. Zhu, H.   Feng, S.C. Zhang, B.B. Zhang, P.B. Wang, and G.H. Liu. Effect of   solidification pressure on compactness degree of 19Cr14Mn0.9N high nitrogen   steel using CAFE method, Steel Research International,   2017, 88(7):1~12.

50H.B. Li, E.Z. Zhou,   Y.B. Ren et al. Investigation of microbiologically influenced corrosion of   highnitrogen nickel-free stainless steel by Pseudomonas aeruginosa, Corrosion   Science, 2016, 111: 811–821.

51H.B. Li*, B.B. Zhang, Z.H. Jiang, et al. A new   insight into high-temperature oxidation mechanism of super-austenitic   stainless steel S32654 in air, Journal of Alloys and Compounds,   2016, 86: 326-338.

52H.B. Li*, Z.H. Jiang, H. Feng, et al. Microstructure,   mechanical and corrosion properties of friction stir welded high nitrogen   nickel-free austenitic stainless steel, Materials and Design, 84 (2015)   291-299.

荣誉称号:

12020年辽宁省百千万人才工程-“百人层次

22019年辽宁省兴辽英才计划科技创新领军人才

32020年第十二届辽宁省优秀科技工作者

42019年第九届中国金属学会冶金青年科技奖

52019年第四批青海省高端创新人才千人计划拔尖人才

62020年第十四届沈阳市优秀科技工作者

72020年沈阳市领军人才;

82019年建龙特聘钢铁集团教授;

92019荣程祥青科研创新奖二等;

102020东北大学优秀教师

112020东北大学第五届“我心目中的好导师”-“研精善教奖”;

122016年东北大学青年岗位能手

132016年东北大学钢铁共性技术协同创新中心创新标兵

142014年辽宁省和东北大学大学生创新创业大赛优秀指导教师

152013-2014年度东北大学优秀班导师

162014年东北大学优秀博士后

172020年冶金学院“优秀共产党员”;

1820182019年获评东北大学冶金学院科研工作先进个人

科研奖励:

1)高性能系列超级不锈钢关键制备技术开发及应用,2021年辽宁省科技进步一等奖(通过会评),个人总排名第1

2)高品质特殊钢绿色高效电渣重熔关键技术的开发和应用,2019年度国家科技进步一等奖,个人总排名第7,校内个人排第3

3)高品质双相不锈钢系列板材关键制备技术开发及应用,中国钢铁工业协会2018年度冶金科技进步一等奖,个人总排名第3,校内个人排第1

4)高性能超级奥氏体不锈钢系列板材关键工艺技术及产品开发,中国钢铁工业协会2015年度冶金科技进步二等奖,个人总排名第2,校内个人排第1

5)高质量宽幅不锈钢光亮板全流程生产线自主集成与关键技术开发,2014年度山西省科技进步一等奖,个人总排名第7,校内个人排第1

6)国际热核聚变实验堆用不锈钢关键材料及制造技术开发,2014年度山西省科技进步二等奖,个人总排名第8,校内个人排第1

社会兼职

1Metallurgical and Materials   Transactions BKey Reader);

2)《钢铁研究学报》编委;

3)《中南大学学报(英文版)》首届青年编委;

4)《矿物冶金与材料学报(英文版)》第一届青年编委;

5)《材料工程》和《航空材料学报》青年编委;

6)辽宁科技大学兼职博士生导师。

个人寄语宁静致远

  


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