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低合金結(jié)構(gòu)鋼及特殊鋼開發(fā)
鎂、鈦、鋁有色金屬材料開發(fā)
軋制、鍛造、焊接、熱處理加工工藝
材料組織與性能控制

《塑性工程學報》、《軋鋼》期刊編委
新能源汽車輕量化技術(shù)安徽省重點實驗室主任委員

1994.09-1998.07 南昌航空大學材料學院學士學位
1998.09-2001.03 南昌航空大學材料學院碩士學位
2001.03-2004.05 西北工業(yè)大學材料學院博士學位
2004.05-2006.03 北京科技大學材料學院博士后
2006.04-至今 北京科技大學工程技術(shù)研究院(原冶金工程研究院)，歷任助理研究員、副研究員、研究員；博士生導師

[1] ZHANG S, JIANG H, XIN J, et al. The investigation of high-temperature shear deformation mechanism in Ti-44Al-4Nb-1.5Mo-0.1B alloy [J]. Materials Science and Engineering: A, 2025, 934.
[2] YU B, JIANG H, ZHANG Y. Superior specific capacity and energy density simultaneously achieved by Sr/In co-deposition behavior of Mg-Sr-In ternary alloys as anodes for Mg-Air cells [J]. Journal of Magnesium and Alloys, 2025, 13(2): 640-53.
[3] LIU W, ZHANG R, WU X, et al. Multi-scale simulation of grain evolution during indirect squeeze casting with considering solute suppressed nucleation and externally solidified crystals [J]. Journal of Materials Processing Technology, 2025, 342.
[4] LIU W, ZHANG R, WU X, et al. Simulation of grain refinement of Al-8Si-0.2 Mg alloy inoculated with Al-Nb-B via an improved cellular automaton model [J]. Materials and Design, 2025, 249.
[5] CHEN F, JIANG H, ZHANG Y, et al. First-principles study on the diffusion of interstitial hydrogen in rare earth doped α-Fe [J]. International Journal of Hydrogen Energy, 2025, 133: 363-76.
[6] YU B, JIANG H, ZHANG Y. Discharge performance and behavior of Mg-xSr binary alloys as novel anodes for primary Mg-Air cells [J]. Journal of Power Sources, 2024, 602.
[7] YU B, JIANG H. Illustrating the influence of anodic/cathodic second-phases on dissolution mode via Mg–Ca–Sn alloy anodes for primary Mg-air cells [J]. Journal of Materials Research and Technology, 2024, 33: 6102-13.
[8] WU B Y, WANG T, ZHANG Y, et al. Hot deformation behavior and microstructure evolution of a novel Mn-containing HEA [J]. Intermetallics, 2024, 169.
[9] WANG T, WU Y, JIANG H. Effect of matrix reversible transition on mechanical and tribological properties of a novel Co-free high-entropy alloy [J]. Journal of Alloys and Compounds, 2024, 1003.
[10] WANG T X, WU Y X, LIU W Q, et al. Roles of Al/Ni ratio and solidification cooling rate in grain boundary engineering of AlxCrFeMnNi(2-x) high entropy alloy [J]. Materials Characterization, 2024, 218.
[11] TIAN S, ZHANG Y, JIANG H, et al. Effect of micron/nano Nb particles on high-temperature oxidation behavior of TiAl alloy/thermal barrier coating system [J]. Surface and Coatings Technology, 2024, 492.
[12] LIU W, ZHANG R, WU X, et al. Microstructure and mechanical properties of non-heat-treated Al–8Si-0.2Mg-0.5Mn alloy inoculated by Al–Nb–B refiner [J]. Journal of Materials Research and Technology, 2024, 31: 1054-66.
[13] ZHANG Y, JIANG H, TIAN S, et al. High temperature oxidation resistance of TNM alloy coated with/without 8YSZ/NiCoCrAlY thermal barrier coatings [J]. Applied Surface Science, 2023, 611.
[14] ZHANG B Y, JIANG H, ZHANG S, et al. Hot salt corrosion behavior of the Ti-44Al-4Nb-1.5Mo-(B,Y) alloy in the temperature range of 750–950 °C [J]. Journal of Materials Research and Technology, 2023, 26: 4887-901.
[15] YANG Y, NEDING B, LI R, et al. Revealing the interdependence of load partitioning, dislocation density evolution and mechanical behavior of medium Mn steels [J]. Materials Science and Engineering: A, 2023, 880.
[16] WANG T, WU Y, YANG Y, et al. Effect of Al/Ni ratio on phase, microstructure and mechanical properties of the AlxCrFeMnNi2-x high entropy alloys [J]. Journal of Alloys and Compounds, 2023, 941.
[17] GUO W, WANG S, LI G, et al. Self-sharpening mechanism of kinetic energy penetrator nose constructed of tungsten-fiber-reinforced Cu–Zn matrix composite [J]. Journal of Materials Research and Technology, 2023, 24: 1589-96.
[18] CHEN F, JIANG H, ZHANG Y, et al. First-principles calculation of bonding and hydrogen trapping mechanism of Fe3C/α-Fe interface [J]. Journal of Materials Research and Technology, 2023, 26: 6782-93.
[19] ZHANG Y, JIANG C, YANG Q, et al. Orientation behavior in TRC-ZA21 magnesium alloy with fine grain size during nano-indentation process [J]. Materials Science and Engineering: A, 2022, 846.
[20] YANG Y G, MU W Z, LI X Q, et al. Effects of strain rate on austenite stability and mechanical properties in a 5Mn steel [J]. Journal of Iron and Steel Research International, 2022, 29(2): 316-26.
[21] WANG P, JIANG H, WANG Y, et al. Role of Microalloyed Y and Gd in Improving the Corrosion Resistance of Rolled Mg-3Al-1Zn Alloy [J]. Acta Metallurgica Sinica (English Letters), 2022, 35(6): 941-7.
[22] TIAN S, ZHANG Y, HE A, et al. Interdiffusion mechanism at the interface between TiAl alloy and NiCoCrAlY bond coating [J]. Surface and Coatings Technology, 2022, 444.
[23] TIAN S, HE A, LIU J, et al. Investigation of the Thermal Shock Behavior of Mo-Containing TiAl Alloys [J]. Adv Eng Mater, 2022, 24(3).
[24] LI L, ZHANG R, YUAN Q, et al. An integrated approach to study the hot tearing behavior by coupling the microscale phase field model and macroscale casting simulations [J]. Journal of Materials Processing Technology, 2022, 310.
[25] ZHANG Y, JIANG H, WANG S, et al. Simultaneous improvements in strength and formability of modified Mg–2Zn alloys by alloying addition and twin-roll casting process [J]. Materials Science and Engineering: A, 2021, 804.
[26] YANG Y, MU W, SUN B, et al. New insights to understand the strain-state-dependent austenite stability in a medium Mn steel: An experimental and theoretical investigation [J]. Materials Science and Engineering: A, 2021, 809.
[27] WU X, LIN H, WANG Y, et al. Hydrogen embrittlement and fracture mechanism of friction stir welded quenching and partitioning 980 steel [J]. Materials Science and Engineering: A, 2021, 802.
[28] WU X, LIN H, LUO W, et al. Microstructure and microhardness evolution of thermal simulated HAZ of Q&P980 steel [J]. Journal of Materials Research and Technology, 2021, 15: 6067-78.
[29] TIAN S, HE A, LIU J, et al. Investigation on the microstructure evolution and dynamic recrystallization mechanisms of TiAl alloy at elevated temperature [J]. Journal of Materials Research and Technology, 2021, 14: 968-84.
[30] ZHANG Y, JIANG H, KANG Q, et al. Microstructure evolution and mechanical property of Mg-3Al alloys with addition of Ca and Gd during rolling and annealing process [J]. Journal of Magnesium and Alloys, 2020, 8(3): 769-79.
[31] WANG Y, ZHANG Y, WANG P, et al. Effect of LPSO phases and aged-precipitations on corrosion behavior of as-forged Mg–6Gd–2Y–1Zn–0.3Zr alloy [J]. Journal of Materials Research and Technology, 2020, 9(4): 7087-99.

1.北京科技大學教育教學成果獎特等獎
2.2020年“第七屆研師亦友-我最喜愛的導師稱號”
3.2017年“高級別汽車板關(guān)鍵技術(shù)創(chuàng)新與應用”項目獲得河北省科技進步一等獎
4.2009年“高鋼級X70~X80熱軋管線鋼的研制”項目獲冶金科技進步二等獎
5.2009年“高鋼級X70~X80熱軋管線鋼的研制”項目獲安徽省科技進步一等獎

[1]楊永剛,米振莉,常江,雷明鋼,何方,衛(wèi)志超,江海濤,吳彥欣.一種淬火配分鋼及其加工方法:北京市,CN115569985B[P].2025-05-13
[2]劉立輝,江海濤,王彬,張韻,沈憲棟,劉占鋒,李磊,郝朝鑫,張曉寧,王信威.一種提高熱軋普碳鋼卷表面質(zhì)量的方法:河北省,CN114918263B[P].2025-05-06
[3]吳彥欣,張淇,劉航瑞,米振莉,江海濤,陳雨來,田世偉.一種可用于熱加工的涂層鋼板及其制備方法和應用:北京市,CN119662125A[P].2025-03-21
[4]吳彥欣,張淇,趙一霖,米振莉,江海濤,胡水平,武曉燕.一種金屬表面鋁硅合金鍍層的修補方法:北京市,CN119608539A[P].2025-03-14
[5]吳彥欣,張淇,劉航瑞,米振莉,江海濤,陳雨來,胡水平.一種用于金屬表面的復合防護涂層及其制備方法:北京市,CN119592222A[P].2025-03-11
[6]江海濤,武曉燕,劉文強,許磊,汪育晶.鋁硅合金及其制備方法與應用、鋁硅合金制品:北京市,CN119410972A[P].2025-02-11
[7]鐘海清,吳春紅,袁靜,田世偉,江海濤,陳濤,謝芳,王小云,楊源華,唐小勇.一種高強搪瓷鋼及其制備方法:江西省,CN118668135A[P].2024-09-20
[8]江海濤,于博文,吳彥欣,武曉燕,田世偉.一種Mg-Ca-Sn-In陽極材料及其制備方法和應用:北京市,CN118600293A[P].2024-09-06
[9]韓建勝,何春雨,江海濤,張立杰,鄧宏玉,宋博瀚,詹智敏,韓爽.一種遮蔽裝置控制系統(tǒng):北京市,CN114713639B[P].2024-08-23
[10]何春雨,宋博瀚,韓爽,張立杰,韓建勝,井梁,江海濤,余偉,陳雨來.一種兼顧節(jié)能與高冷速的熱軋帶鋼的冷卻供水系統(tǒng):北京市,CN118207933A[P].2024-06-18
[11]江海濤,于博文,吳彥欣,張韻.一種鎂空氣電池用鎂鍶合金陽極材料及其制備方法與應用:北京市,CN118156524A[P].2024-06-07
[12]楊永剛,米振莉,常江,雷明鋼,何方,衛(wèi)志超,江海濤,吳彥欣.一種淬火配分QP980與QP1180非等強度鋼材的焊接工藝:北京市,CN115464242B[P].2024-05-10
[13]江海濤,武曉燕,劉文強,路洪洲,郭愛民.一種汽車用高強高韌含Nb免熱處理鋁硅銅鎂合金及其制備方法:北京市,CN117987700A[P].2024-05-07
[14]江海濤,武曉燕,劉文強,路洪洲,郭愛民.一種汽車薄壁件用高強高韌含Nb免熱處理鋁鎂合金及其制備方法:北京市,CN117965974A[P].2024-05-03
[15]張隨鵬,劉濤,詹智敏,江海濤,劉琦峰,劉鵬飛.一種冶金自動化熱軋鋼管冷卻裝置:北京市,CN220717225U[P].2024-04-05
[16]武曉燕,江海濤,劉文強.一種新能源汽車用含Nb免熱處理鋁硅合金及其制備方法:北京市,CN117737522A[P].2024-03-22
[17]江海濤,于博文,吳彥欣,張韻.一種鎂空氣電池用Mg-Sr-In合金陽極材料及其制備方法:北京市,CN117721353A[P].2024-03-19
[18]田世偉,江海濤,張思遠,張業(yè)飛,楊禎彧,朱志超,劉建華,何安瑞,張勇軍,陳雨來.仿異步軋制的TiAl合金異形坯包套軋制方法及TiAl合金板材:北京市,CN117225922A[P].2023-12-15
[19]江海濤,武曉燕,劉文強.一種含鈮免熱處理鋁合金及其制備方法:北京市,CN117165819A[P].2023-12-05
[20]袁靜,鐘海清,江海濤,唐小勇,張韻,王小云,冷燁旻,李世桓,陳濤.一種耐高溫搪燒的屈服強度360MPa級低碳熱軋高強搪瓷鋼及其生產(chǎn)方法:江西省,CN116694997A[P].2023-09-05
[21]徐言東,白金龍,郭強,張勇軍,白英超,程知松,江海濤,韓爽,胡博.一種適于帶式輸送機膠帶縱向撕裂的檢測系統(tǒng):北京市,CN115818161B[P].2023-09-01
[22]田世偉,張業(yè)飛,江海濤,張思遠,張騰坤,楊禎彧,楊永剛,張韻,吳彥欣.基于疊覆結(jié)構(gòu)設計的鍛態(tài)TiAl合金薄板包套軋制方法:北京市,CN116603860A[P].2023-08-18
[23]徐言東,白金龍,郭強,程知松,張勇軍,白英超,余偉,劉濤,韓爽,張立杰,何春雨,江海濤,詹智敏,鄧宏玉.一種帶式輸送機倒帶斷帶檢測設備及方法:北京市,CN114604598B[P].2023-04-07
[24]徐言東,白金龍,郭強,張勇軍,白英超,程知松,江海濤,韓爽,胡博.一種適于帶式輸送機膠帶縱向撕裂的檢測系統(tǒng):北京市,CN115818161A[P].2023-03-21
[25]詹智敏,劉濤,張隨鵬,江海濤,張立杰.一種可視化中厚板冷卻器自水冷循環(huán)保護裝置及方法:北京市,CN114367552B[P].2023-01-20
[26]楊永剛,米振莉,常江,雷明鋼,何方,衛(wèi)志超,江海濤,吳彥欣.一種淬火配分鋼及其加工方法:北京市,CN115569985A[P].2023-01-06
[27]楊永剛,米振莉,常江,雷明鋼,何方,衛(wèi)志超,江海濤,吳彥欣.一種淬火配分QP980與QP1180非等強度鋼材的焊接工藝:北京市,CN115464242A[P].2022-12-13
[28]詹智敏,劉濤,張隨鵬,江海濤,張立杰,徐言東.一種快速響應多級阻尼板帶鋼冷卻器:北京市,CN217912191U[P].2022-11-29
[29]劉立輝,江海濤,王彬,張韻,沈憲棟,劉占鋒,李磊,郝朝鑫,張曉寧,王信威.一種改善熱軋帶鋼氧化鐵皮狀態(tài)的蒸氣噴霧裝置:河北省,CN217798112U[P].2022-11-15
[30]徐言東,白金龍,郭強,程知松,張勇軍,白英超,余偉,劉濤,韓爽,張立杰,何春雨,江海濤,詹智敏,鄧宏玉.一種帶式輸送機倒帶斷帶檢測設備:北京市,CN217779898U[P].2022-11-11
[31]詹智敏,劉濤,張隨鵬,江海濤,張立杰,徐言東.一種快速響應多級阻尼板帶鋼冷卻器及冷卻方法:北京市,CN115213244A[P].2022-10-21
[32]劉濤,陳雨來,余偉,江海濤,米振莉,李小占,張勇軍,井梁,殷實.一種提高貝氏體鋼軋后冷卻溫度精度的方法:北京市,CN111069309B[P].2021-04-06
[33]劉濤,余偉,陳雨來,江海濤,米振莉,張立杰,井梁,詹智敏.一種中厚板淬火機防水錘方法:北京市,CN111154967B[P].2021-04-06
[34]江海濤,楊永剛,米振莉,吳彥欣,田世偉,王家毅.一種含亞穩(wěn)奧氏體相的高強鋼回彈測定方法:北京市,CN110333128B[P].2020-12-22
[35]劉濤,陳雨來,江海濤,余偉,李小占,米振莉,張隨鵬,何安瑞.一種中厚板軋后加速冷卻工藝節(jié)水方法:北京市,CN111906154A[P].2020-11-10
[36]劉濤,高照海,余偉,詹智敏,陳雨來,江海濤,何安瑞,郭強.一種與去毛刺機緊湊布置的鑄坯冷卻方法:北京市,CN111745137A[P].2020-10-09
[37]武曉燕,江海濤,米振莉,吳彥欣,劉建華.一種鈦鋼層狀復合薄卷制備方法:北京市,CN111672904A[P].2020-09-18
[38]劉濤,余偉,陳雨來,江海濤,張立杰,米振莉,張勇軍,高照海.一種提高鑄坯溫度均勻性的鑄坯冷卻方法:北京市,CN111618264A[P].2020-09-04

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