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王煒哲
研究員所在系所:葉輪機(jī)械研究所
辦公電話:021-34205083
電子郵件:wangwz0214@sjtu.edu.cn
通訊地址:上海交大機(jī)械與動(dòng)力工程學(xué)院A樓537室
個(gè)人主頁(yè): AI (人工智能) + Mechanics (力學(xué)) + Chip(芯片) ,招收碩士、博士、博士后
教育背景
2003.09 - 2007.10,上海交通大學(xué),動(dòng)力機(jī)械及工程,博士
2000.09 - 2003.06,上海交通大學(xué),動(dòng)力機(jī)械及工程,碩士
1996.09 - 2000.06,河海大學(xué), 熱能動(dòng)力工程, 學(xué)士
工作經(jīng)歷
2010.04 - :上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院 / 葉輪機(jī)械研究所 / 助理研究員、副研究員、研究員 / 博士生導(dǎo)師
2012-2013、2014、2015: 德國(guó)斯圖加特大學(xué)MPA / 訪問(wèn)學(xué)者
2007.11 - 2010.03: 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院 / 機(jī)械工程 / 博士后
研究方向
招收如下相關(guān)專業(yè)的博、碩士研究生,以及博士后。
動(dòng)力工程及工程熱物理;機(jī)械工程;航空航天;計(jì)算機(jī)軟件;流體力學(xué);固體力學(xué);數(shù)學(xué);物理;光學(xué)。
關(guān)鍵詞:數(shù)字孿生,物理超降階/數(shù)據(jù)降階,機(jī)器學(xué)習(xí),超精密結(jié)構(gòu)時(shí)空熱力變形,直接逆向預(yù)測(cè),高溫結(jié)構(gòu)強(qiáng)度,蠕變疲勞損傷
1.高溫結(jié)構(gòu)強(qiáng)度預(yù)測(cè)及全周期壽命評(píng)估(力學(xué)本構(gòu),數(shù)值算法:汽輪機(jī)/燃?xì)廨啓C(jī)/空氣透平、儲(chǔ)能裝備)
2.極端稀疏傳感器驅(qū)動(dòng)高溫結(jié)構(gòu)熱力數(shù)字孿生技術(shù)(降階/超降階:裝備結(jié)構(gòu)內(nèi)三維空間熱力狀態(tài))
3.近場(chǎng)動(dòng)力學(xué):力-熱-化交互作用下金屬材料結(jié)構(gòu)漸進(jìn)損傷預(yù)測(cè)
4.傳感與計(jì)算融合的力-熱耦合損傷預(yù)測(cè)、材料屬性逆向預(yù)測(cè)及結(jié)構(gòu)健康評(píng)估
5.光-熱-力耦合的集成電路中結(jié)構(gòu)熱變形預(yù)測(cè)
6.極端環(huán)境下的結(jié)構(gòu)熱力協(xié)同管理(發(fā)動(dòng)機(jī)熱端部件,新能源電動(dòng)車電池?zé)峁芾恚?br/>7.邊緣端計(jì)算:FPGA + 數(shù)字孿生體技術(shù)的高溫裝備熱力狀態(tài)采算一體化
8.整套工業(yè)裝備結(jié)構(gòu):閥門/汽缸/轉(zhuǎn)子/葉片/密封等工業(yè)部件結(jié)構(gòu)強(qiáng)度預(yù)測(cè)
9.物理驅(qū)動(dòng)降階/超降階技術(shù)的工業(yè)部件快速優(yōu)化設(shè)計(jì)
學(xué)術(shù)兼職
13)《Materials: Metals and Alloys》, 編委
12)《熱能動(dòng)力工程》,編委
11)The 15th Asia-Pacific Conference on Fracture and Strength, Scientific Committee,Session Chair, Invited Speaker
10)2018-,中國(guó)機(jī)械工程學(xué)會(huì)材料分會(huì)青年委員會(huì),委員
9)ASME PVP Committee Member
8)ASME PVP Conference Session Organizer
7)TURBO EXPO 2018(ASME Turbo Expo): Session Organizer, Session Chair
6)TURBO EXPO 2017(ASME Turbo Expo, Power & Energy and ICOPE): Session Organizer, Session Chair
5)ASME TURBO EXPO 2016:Session Co-Chair (COMM 27 Structures & Dynamics: Emerging Methods in Design & Engineering: Optimization & New Methods Development)
4)2016 NexTurbine 第五屆下一代燃?xì)廨啓C(jī)峰會(huì),分會(huì)場(chǎng)主席
3)2016-, 中國(guó)造船工程學(xué)會(huì)輪機(jī)學(xué)術(shù)委員會(huì)輔機(jī)分會(huì),委員
2)2012-, 國(guó)際期刊《Recent Patents on Mechanical Engineering》編委
1)山東省“能源計(jì)量與節(jié)能減排”專家論壇大會(huì)上作為特邀專家
基于數(shù)字孿生的裝備測(cè)試技術(shù),授課對(duì)象:研究生,學(xué)時(shí):16,學(xué)分1
(如何利用降維技術(shù)手段,結(jié)合傳感器采集數(shù)據(jù),實(shí)現(xiàn)在線或準(zhǔn)在線快速全場(chǎng)預(yù)測(cè))
能源裝備與工業(yè)大數(shù)據(jù)分析,授課對(duì)象:研究生,學(xué)時(shí):32,學(xué)分2
(在維持高精度情況下,如何進(jìn)行降維快速計(jì)算,面向工業(yè)數(shù)據(jù)或?qū)ο螅_展數(shù)據(jù)增強(qiáng)、挖掘、以及分析)
機(jī)械與動(dòng)力仿真實(shí)踐(能動(dòng)類),授課對(duì)象:本科,學(xué)時(shí):64,學(xué)分4
(高維+高保真計(jì)算方法:CFD+FEM,實(shí)現(xiàn)流動(dòng)、傳熱、結(jié)構(gòu)強(qiáng)度的計(jì)算分析,了解底層計(jì)算原理和如何開展工程應(yīng)用)
++++++++++++++++++++++++
畢業(yè)的博士:
董含(2025畢業(yè),國(guó)家獎(jiǎng)學(xué)金,佐治亞大學(xué),博士后)《能源裝備材料與結(jié)構(gòu)裂紋演化的近場(chǎng)動(dòng)力學(xué)模型》
王涵(2024畢業(yè),國(guó)家獎(jiǎng)學(xué)金,哈爾濱工業(yè)大學(xué),師資博士后)《基于近場(chǎng)動(dòng)力學(xué)方法的腐蝕影響下葉片材料疲勞斷裂性能退化研究》
寧路源(2024畢業(yè),國(guó)際會(huì)議DACOMA-23最佳演講獎(jiǎng),斯坦福大學(xué),博士后)《基于數(shù)據(jù)-物理驅(qū)動(dòng)深度學(xué)習(xí)的非均質(zhì)結(jié)構(gòu)強(qiáng)度預(yù)測(cè)》
江耿輝(2024畢業(yè),南京理工大學(xué),講師)《模型降階驅(qū)動(dòng)下高溫部件熱力行為快速預(yù)測(cè)技術(shù)及應(yīng)用研究》
RICHARD AMANKWA ADJEI(2020畢業(yè),寧波諾丁漢大學(xué),Assistant Professor)《Multi-Objective Design Optimization for Performance Improvement of a Turbocharger Compressor using Arbitrary Shape Deformation》
洪 輝 (2020畢業(yè),中國(guó)商發(fā),“心”計(jì)劃)《靈活運(yùn)行工況下汽輪機(jī)轉(zhuǎn)子結(jié)構(gòu)強(qiáng)度與損傷分析》
蔡振威 (2020畢業(yè),YLS,上海市“超級(jí)博士后”計(jì)劃,國(guó)家自然科學(xué)青年基金)《CMAS滲透下熱障涂層強(qiáng)度及耦合冷卻孔對(duì)其影響的研究》
蔣季伸 (2019畢業(yè),中山大學(xué),副教授)《燃?xì)廨啓C(jī)熱障涂層界面失效及含冷卻孔涂層的多層結(jié)構(gòu)強(qiáng)度分析》
趙乃龍 (2018畢業(yè),阿里巴巴,算法工程師)《基于宏-介觀力學(xué)方法的超超臨界汽輪機(jī)轉(zhuǎn)子蠕變-疲勞強(qiáng)度評(píng)估》
毛劍峰 (2014畢業(yè),與劉應(yīng)征聯(lián)合指導(dǎo),浙江工業(yè)大學(xué),副教授)《超超臨界汽輪機(jī)進(jìn)汽閥結(jié)構(gòu)強(qiáng)度與壽命分析》
焦廣臣 (2014畢業(yè),與劉應(yīng)征聯(lián)合指導(dǎo),上海輝策信息科技有限公司,資深技術(shù)經(jīng)理)《核電汽輪機(jī)低壓轉(zhuǎn)子葉根槽應(yīng)力腐蝕與安全性評(píng)估》
畢業(yè)的碩士:
衡 元(2026畢業(yè),本課題組攻讀博士學(xué)位,設(shè)計(jì)端:伴隨結(jié)構(gòu)特征變化的自適應(yīng)降階算法)
高開楠(2025畢業(yè),華為,結(jié)構(gòu)和材料工程師)
張鐘文(2025畢業(yè),阿里巴巴平頭哥,半導(dǎo)體)
劉瑩慧(2025畢業(yè),盛美半導(dǎo)體設(shè)備(上海)股份有限公司,集成電路/晶圓制造等)
李宇航(2024畢業(yè),上海飛機(jī)設(shè)計(jì)研究院,信息化)
朱蘭馨(2024畢業(yè),上海電氣發(fā)電機(jī)廠)
何新宇(2022畢業(yè),中國(guó)商發(fā))
陳強(qiáng)強(qiáng)(2021畢業(yè),阿里巴巴,算法工程師)
羅淇元(2021畢業(yè),阿里巴巴,算法工程師)
張子凡 (2021畢業(yè),英格索蘭)
蔣凌欣(2020畢業(yè),日本東京電子)
牛鵬坤(2020畢業(yè),深圳 TP-LINK)
李 乾 (2020畢業(yè),上海交通大學(xué),博士生)
趙文辰(2019畢業(yè),美國(guó)密西根大學(xué))
馬思琦(2019畢業(yè),遠(yuǎn)景能源)
吳 穹 (2015畢業(yè),中國(guó)航天科工集團(tuán)第九總體設(shè)計(jì)部)
喻 超 (2014畢業(yè),華東電力設(shè)計(jì)研究院)
戴 偉 (2011畢業(yè),霍尼韋爾汽車零部件服務(wù)(上海)有限公司)
鄔文睿(2009畢業(yè),上汽集團(tuán))
亮點(diǎn)工作
近3年的10篇代表性論文:(唯一通訊作者)
=> 近場(chǎng)動(dòng)力學(xué)方向:
1) Luyuan Ning, Zhenwei Cai, Han Dong, Yingzheng Liu, Weizhe Wang, Physics-informed neural network frameworks for crack simulation based on minimized peridynamic potential energy, Computer Methods in Applied Mechanics and Engineering, 2023, 417: 116430-1-20.
2)Luyuan Ning, Zhenwei Cai, Han Dong, Yingzheng Liu, Weizhe Wang, A peridynamic-informed neural network for continuum elastic displacement characterization, Computer Methods in Applied Mechanics and Engineering, 2023, 407: 115909-1-24
3)Han Dong, Han Wang, Weizhe Wang, Yingzheng Liu, A non-ordinary state-based peridynamic model for creep–fatigue behavior and damage evolution, International Journal of Fatigue, 2024, 184:108324
4)Han Wang, Han Dong, Zhenwei Cai, Yingzhengliu ,Weizhe Wang, Fatigue behaviors of a nickel-based superalloy after hot-corrosion: experiments and peridynamic simulations, International Journal of Fatigue, 2024, 180: 108070-1-21
5)Han WANG, Zhenwei CAI, Han DONG, Yingzheng LIU, Weizhe Wang, Mechanical-chemical-coupled peridynamic model for the corrosion fatigue behavior of a nickel-based alloy, International Journal of Fatigue, 2023,168: 107400-1-16
=>降階方向
6)Han Dong, Hongjiang Wang, Jiahao Zhong, Chaohui Huang, Weizhe Wang, Yingzheng Liu, A snapshot-free reduced-order peridynamic model for accelerating fracture analysis of composites, Computer Methods in Applied Mechanics and Engineering, 2025, 437: 117777.
7)Han Dong, Hongjiang Wang, Jiahao Zhong, Chaohui Huang, Weizhe Wang, Yingzheng Liu, Geometry-adaptive peridynamics for fast simulation of mechanical and thermal behaviors under varying geometries, International Journal for Numerical Methods in Engineering, 2025, 126:1-27
8)Han Dong, Hongjiang Wang, Chaohui Huang, Jiahao Zhong, Weizhe Wang, Yingzheng Liu, Reduced-order peridynamics for efficient simulation of fracture in a turbine blade root, Engineering Fracture Mechanics, 2025, 313: 110636.
9) Han Dong, Dasheng Wang, Hongjiang Wang, Chaohui Huang, Jiahao Zhong, Weizhe Wang, Yingzheng Liu, Reduced-order peridynamics for accelerated thermo-mechanical failure analysis of reactor pressure vessels, Fatigue & Fracture of Engineering Materials & Structures, 2026; 49:156–169
10)Genghui Jiang, Ming Kang, Zhenwei Cai, Han Wang, Yingzheng Liu, Weizhe Wang, Efficient reduced-order model for multiaxial creep–fatigue analysis based on a unified viscoplastic constitutive model, International Journal of Fatigue, 2023, 175: 107787-1-11
亮點(diǎn)工作展示
※ 以控制系統(tǒng)為底座的整個(gè)電廠數(shù)字孿生系統(tǒng):純物理方程
※ 熱力數(shù)字孿生體: 保留物理方程和離散格式的超降階技術(shù) (利用現(xiàn)場(chǎng)已有的少量傳感器:譬如 溫度、壓力、流量)
1. 依然保有物理方程;2. 依然保留離散方程;3. 具有物理可解釋性、魯棒性強(qiáng)、泛化能力好;4. 在線預(yù)測(cè)全三維空間信息
※ AI for Engineering :無(wú)數(shù)據(jù)集的應(yīng)力/位移、以及裂紋預(yù)測(cè)技術(shù),預(yù)測(cè)結(jié)構(gòu)從完整到斷裂的自然演化過(guò)程
1. 連續(xù)位移場(chǎng)的預(yù)測(cè);2. 結(jié)構(gòu)從完整無(wú)損到斷裂過(guò)程;3. 知識(shí)融入的機(jī)器學(xué)習(xí)網(wǎng)絡(luò)架構(gòu)
※ 近場(chǎng)動(dòng)力學(xué)PD在工業(yè)部件中的應(yīng)用:描述結(jié)構(gòu)從完整無(wú)損到斷裂的自然演化過(guò)程,無(wú)需預(yù)先設(shè)置裂紋路徑或區(qū)域。
1. 蠕變疲勞損傷的重述;2. 方程中的參數(shù)擬合及工業(yè)級(jí)數(shù)據(jù)驗(yàn)證;3. 樣件的試驗(yàn)驗(yàn)證
※ 基于有限元的工業(yè)應(yīng)用 (復(fù)雜部件和裝配系統(tǒng)三維空間的蠕變-疲勞-損傷、壽命、健康:包括 溫度、應(yīng)力/應(yīng)變、多軸系數(shù)、損傷分布)
1. 本構(gòu)模型的應(yīng)用和構(gòu)建;2. 本構(gòu)模型的數(shù)據(jù)擬合;3. 復(fù)雜部件蠕變、疲勞、損傷全耦合計(jì)算及評(píng)價(jià)
科研項(xiàng)目
主持項(xiàng)目:
縱向/國(guó)際合作項(xiàng)目:
2025-2027,國(guó)家級(jí)項(xiàng)目,近場(chǎng)動(dòng)力學(xué)在核承壓設(shè)備斷裂力學(xué)分析中的應(yīng)用研究
2024-2025,國(guó)防項(xiàng)目,禁固件力-熱環(huán)境下失效行為力學(xué)分析
2022-2023,揭榜掛帥,燃機(jī)透平葉片強(qiáng)度評(píng)估及裂紋預(yù)測(cè)技術(shù)研究
2021-2022,國(guó)際合作,單傳感數(shù)據(jù)驅(qū)動(dòng)下高速旋轉(zhuǎn)部件熱力行為快速預(yù)測(cè)
2019-2022,國(guó)家自然科學(xué)基金面上項(xiàng)目,燃?xì)廨啓C(jī)葉片含孔熱障涂層中TGO熱生長(zhǎng)及其對(duì)涂層多層結(jié)構(gòu)應(yīng)力演化影響的研究
2018-2021,國(guó)家級(jí)課題,高溫合金材料和結(jié)構(gòu)腐蝕疲勞
2016-2019,國(guó)際合作,材料老化特性對(duì)斷裂力學(xué)參數(shù)影響的方法研究
2016-2017,國(guó)際合作,Design optimization of compressor impeller with optimization tool
2015-2016,國(guó)際合作,Rotor disk 3D feature analysis and optimization method study
2015-2016,國(guó)際合作,高溫部件試驗(yàn)及剩余壽命評(píng)估
2011-2013,國(guó)防項(xiàng)目,點(diǎn)發(fā)熱源驅(qū)動(dòng)空間溫度變化分析及結(jié)構(gòu)力學(xué)行為預(yù)測(cè)
2010-2012,國(guó)家自然科學(xué)基金,接觸式高壓氣流密封接觸點(diǎn)傳熱及流固耦合傳熱研究
2009-2010,國(guó)家級(jí)項(xiàng)目,先進(jìn)密封流固熱力預(yù)測(cè)技術(shù)
2010-2011,校級(jí)項(xiàng)目,指尖密封的高溫蠕變及滯后效應(yīng)
其他類型項(xiàng)目
2025-2026,厚壁承壓部件橢圓度快速預(yù)測(cè)及優(yōu)化(稀疏數(shù)據(jù) + HPROM + ML + Sym Reg,混合應(yīng)用技術(shù))
2025-2026,工業(yè)汽輪機(jī)汽缸結(jié)構(gòu)熱力狀態(tài)快速計(jì)算技術(shù)及邊界快速篩選(擴(kuò)充海量設(shè)計(jì)工況范圍 + 極端壓縮設(shè)計(jì)周期)
2025-2026,融合虛擬傳感器方法的高溫復(fù)雜承壓結(jié)構(gòu)健康狀態(tài)預(yù)測(cè)(全三維損傷/材料屬性逆向預(yù)測(cè))
2025-2026,融合傳感器采集數(shù)據(jù)高壓模塊變形及間隙預(yù)測(cè)(核電全三維數(shù)字孿生在線應(yīng)用)
2025-2026,承壓部件結(jié)構(gòu)的熱力變形優(yōu)化分析及建議
2025-2026,低摩擦滑動(dòng)系統(tǒng)的結(jié)構(gòu)熱力變形及優(yōu)化
2023-2024,空氣透平閥門、汽缸、轉(zhuǎn)子、葉片整套系統(tǒng)結(jié)構(gòu)強(qiáng)度及運(yùn)行條件匹配設(shè)計(jì)
2023-2024,核電廠汽輪機(jī)調(diào)門結(jié)構(gòu)變形誘導(dǎo)嚴(yán)密性改進(jìn)
2023-2024,核電汽輪機(jī)末級(jí)長(zhǎng)葉片氣動(dòng)、振動(dòng)及強(qiáng)度研究
2023-2024,復(fù)雜運(yùn)行工況下汽缸法蘭-螺栓結(jié)構(gòu)組件系統(tǒng)的熱力數(shù)字孿生技術(shù)
2023-2024,100MW等級(jí)光熱汽輪機(jī)快速頻繁啟停熱部件壽命分析及啟動(dòng)策略優(yōu)化
2023-2024,高溫段變反動(dòng)度葉片的氣動(dòng)與強(qiáng)度算法研究
2022-2022, H級(jí)聯(lián)合循環(huán)汽輪機(jī)三維數(shù)字孿生體技術(shù)的可視化壽命實(shí)時(shí)在線計(jì)算
2022-2022, H級(jí)聯(lián)合循環(huán)汽輪機(jī)三維數(shù)字孿生體技術(shù)的智能化運(yùn)行方式研究及優(yōu)化
2021-2022,基于虛擬DCS技術(shù)的船用助推動(dòng)力系統(tǒng)數(shù)字化軟件開發(fā)
2021-2022,超低溫(LNG船用)閥門的流動(dòng)和強(qiáng)度預(yù)測(cè)及優(yōu)化技術(shù)
2021-2022,現(xiàn)場(chǎng)傳感數(shù)據(jù)驅(qū)動(dòng)下厚壁部件熱力數(shù)字孿生體
2020-2021,特種閥門的高溫蠕變作用機(jī)制及應(yīng)對(duì)措施
2019-2020,動(dòng)力系統(tǒng)動(dòng)態(tài)性能實(shí)時(shí)仿真及分析
2019-2020,基于虛擬DCS技術(shù)的全范圍、全工況數(shù)字化電站仿真系統(tǒng)
2019-2020,煤電機(jī)組壽命評(píng)估要素分析與延壽策略
2019-2021,鹽霧腐蝕環(huán)境下高溫合金結(jié)構(gòu)疲勞設(shè)計(jì)方法研究
2019-2020,蠕變疲勞交互作用下預(yù)緊配合結(jié)構(gòu)力學(xué)行為研究
2019-2020,蠕變疲勞交互作用下金屬接觸密封的變形及壽命研究
2018-2019,渦輪增壓器整機(jī)結(jié)構(gòu)的流固耦合傳熱
2018-2019,電站全范圍運(yùn)行優(yōu)化的數(shù)字化動(dòng)態(tài)系統(tǒng)研發(fā)
2017-2018,快速冷啟準(zhǔn)則制定、結(jié)構(gòu)優(yōu)化及強(qiáng)度評(píng)估
2016-2018,蠕變疲勞交互作用下局部高溫區(qū)多結(jié)構(gòu)的變形及壽命評(píng)價(jià)研究
2016-2018,快速冷啟承壓結(jié)構(gòu)變形及強(qiáng)度優(yōu)化
2016-2017,HW試驗(yàn)管理平臺(tái)方案設(shè)計(jì)
2016-2017,基于冷卻技術(shù)的700°C閥門結(jié)構(gòu)設(shè)計(jì)及安全評(píng)估方法
2016-2017,700°C下高溫承壓部件結(jié)構(gòu)強(qiáng)度分析及安全評(píng)估流程研究
2015-2017,現(xiàn)役超超臨界機(jī)組關(guān)鍵部位損傷取樣分析技術(shù)研究
2015-2016,高速離心壓縮機(jī)動(dòng)靜干涉作用的數(shù)值研究
2015-2016,燃燒室結(jié)構(gòu)強(qiáng)度分析
2015-2016,1200MW超超臨界中壓模塊強(qiáng)度預(yù)測(cè)及安全評(píng)估
2014-2015,燃?xì)廨啓C(jī)熱端部件強(qiáng)度分析和結(jié)構(gòu)設(shè)計(jì)安全評(píng)估方法研究
2014-2015,蒸汽濾網(wǎng)沖擊性能分析
2014-2015,蒸汽燃?xì)饴?lián)合循環(huán)HIP流動(dòng)換熱及結(jié)構(gòu)安全分析
2012-2013,超高壓承壓部件和高速旋轉(zhuǎn)部件啟停優(yōu)化及蠕變疲勞壽命評(píng)估
2011-2012,大型核電低壓轉(zhuǎn)子應(yīng)力腐蝕疲勞壽命評(píng)估
2011-2012,新型高壓閥門設(shè)計(jì)方法及安全評(píng)估技術(shù)
2011-2012,轉(zhuǎn)動(dòng)部件狹隙環(huán)腔內(nèi)流固耦合傳熱及預(yù)測(cè)技術(shù)
2010-2011,高溫旋轉(zhuǎn)部件蠕變疲勞耦合壽命損傷計(jì)算
2010-2011,高溫部件大螺紋環(huán)及其附件結(jié)構(gòu)分析和設(shè)計(jì)規(guī)范的建立
2009-2010,超超臨界660MW機(jī)組高溫部件蠕變疲勞強(qiáng)度計(jì)算
2009-2010,大飛機(jī)起落架緩沖器密封技術(shù)研究
代表性論文專著
(一作/通訊作者)
=> Yuheng Zhang, Hao Long, Yang Xia, Zhaohui Huang, Weizhe Wang, Yinzheng LIU, Reduced-Order Driven Improved EnKF Method for Online Estimation of Time-Varying Convective Heat Transfer Coefficient and Temperature Field in Lithography Masks, Applied Thermal Engineering, Submitted, 2026
=> Hao Long, Hongjiang Wang, Yuheng Zhang, Weizhe Wang, Yinzheng LIU, Real-time Inverse Modeling for Pipeline Solid Temperature in Conjugate Heat Transfer Using Sparse Sensor-enhanced Reduced-order Model, Nuclear Engineering and Design, Submitted, 2026
=> Hongjiang WANG, Han DONG, Jiahao Zhong, Yang Xia, Weizhe Wang, Yinzheng LIU,A spatial-differential-enriched reduced basis with single-sensor data for iteration-free inverse modeling of unsteady flows,Journal of Computational Physics,Submitted, Dec. 2025
=> Jiahao Zhong, Yang Xia, Ming Kang, Hongjiang Wang, Weizhe Wang, Yinzheng Liu, Topology Optimization-inspired Inverse Identification of Elastic Modulus Distribution Using Boundary Displacement for Material Degradation Assessment, International Journal of Solids and Structures, Submitted, 2025
=> Zhaohui Huang, Xianfeng Chen, Honglei Zhu, Hongjiang Wang, Wenfu Li, Weizhe Wang, Yingzhengliu, Physics-Driven Hyper-Reduced-Order Modeling for Rapid Exploration of Steam Turbine Casing Boundaries and Prediction of Thermal Contact Resistance, International Communications in Heat and Mass Transfer, Under Review, 2026
=> Hongjiang Wang, Han Dong, Chaohui Huang, Weizhe Wang, Yingzheng Liu, Single-Sensor-Driven Hyper Reduced Order Model for Inverse Inference and Error Estimation of 3D Thermo-Mechanical-Material States, International Comunications in Heat and Mass Transfer, Submitted, 2025.
=> Hongjiang Wang, Chaohui Huang, Han Dong, Jiahao Zhong, Weizhe Wang, Yingzhengliu, Real-time inverse inference and error analysis of complex three-dimensional spatial thermal fields from single sensor input, Engineering with Computers, Aug. 2025
2026年論文
[177] Chaohui Huang, Hongjiang Wang, Han Dong, Weizhe Wang , Yingzheng Liu, Invariant Key-Node DEIM Based on Adaptive Mesh Refinement for Efficient Prediction of Transient Thermo-Mechanical Behavior in Valves, International Journal of Thermal Sciences, Accepted, Jan. 2026
2025年論文
[176] Chaohui Huang, Hongjiang Wang, Hongmei Zhang, Weizhe Wang , Yingzheng Liu, A hyper-reduced-order model for the rapid thermal behavior analysis of high-temperature rotor blades, Journal of Thermal Stresses, Accepted, 2025.
[175] Han Dong, Hongjiang Wang, Jiahao Zhong, Chaohui Huang, Weizhe Wang, Yingzheng Liu, Geometry-adaptive peridynamics for fast simulation of mechanical and thermal behaviors under varying geometries, International Journal for Numerical Methods in Engineering, , 2025, 126:1-27
[174] Yuheng Zhang, Yang Xia, Weizhe Wang, Yingzhengliu, Hyper-Reduction-Accelerated Data Assimilation Method in Thermo-mechanical Analysis of Lithography Masks, International Communications in Heat and Mass Transfer, Accepted, 2025.
[173] Han Dong, Dasheng Wang, Hongjiang Wang, Chaohui Huang, Jiahao Zhong, Weizhe Wang, Yingzheng Liu, Reduced-order peridynamics for accelerated thermo-mechanical failure analysis of reactor pressure vessels, Fatigue & Fracture of Engineering Materials & Structures, Accepted, 2025
[172] Jiahao Zhong, Yang Xia, Hongjiang Wang, Han Dong, Weizhe Wang, A boundary displacement–based defect identification method inspired by topology optimization, International Journal of Solids and Structures, Accepted, Jul. 2025.
[171] Hongjiang WANG, Lijie Qiao, Han DONG, Zhaohui HUANG?, Weizhe Wang, Yingzheng LIU, A nonintrusive finite-orthogonal-basis reduced-order model for accelerated computation of geometrically parameterized problems, Engineering with Computers, Accepted, Jun. 2025.
[170] Genghui Jiang, Weizhe Wang, Cheng Cheng, A hyper reduction model for fast thermo-mechanical coupling analysis of high-temperature components, Journal of Thermal Stresses, Accepted, 2025
[169] Han Wang, Kai Huang, Weizhe Wang, Licheng Guo, Peridynamics modelling on corrosion fatigue behaviours of an Iron-based alloy considering mechanochemical effects, European Journal of Mechanics / A Solids, Accepted, 2025
[168] Hongjiang Wang, Han Dong, Chaohui Huang, Weizhe Wang, Yingzhengliu, Physics-sensing framework driven by non-intrusion hyper-reduced-order model with extremely sparse data: Application to an industrial high-temperature component, Energy, Accepted, 2025
[167] Han Wang, Kai Huang, Weizhe Wang , Licheng Guo, Irregular nonuniform peridynamics based fatigue failure analysis of a blade-shroud-like structure, Engineering Fracture Mechanics, 2025, 316: 110867.
[166] Han Dong, Hongjiang Wang, Jiahao Zhong, Chaohui Huang, Weizhe Wang, Yingzheng Liu, A snapshot-free reduced-order peridynamic model for accelerating fracture analysis of composites, Computer Methods in Applied Mechanics and Engineering, 2025, 437: 117777.
[165] Hongjiang Wang, Weizhe Wang, Yingzheng Liu, A finite-orthogonal-basis reduced-order model framework for solving partial differential equations,Physics of Fluids, 2025, 37: 017124.
[164] Han Dong, Hongjiang Wang, Chaohui Huang, Jiahao Zhong, Weizhe Wang, Yingzheng Liu, Reduced-order peridynamics for efficient simulation of fracture in a turbine blade root, Engineering Fracture Mechanics, 2025, 313: 110636.
2024年論文
[163] Hongjiang Wang, Genghui Jiang, Weizhe Wang, Yingzheng Liu, A novel hyper-reduction framework featuring direct projection without an approximation process, Physics of Fluids, 2024, 36: 085176.
[162] Genghui Jiang, Ming Kang, Zhenwei Cai, Han Wang,Yingzheng Liu, Weizhe Wang, Hyper-reduced-order model for estimating convection heat transfer coefficients of turbine rotors, Applied Thermal Engineering, 2024, 256:124103
[161] Han Dong, Han Wang, Weizhe Wang, Yingzheng Liu, A non-ordinary state-based peridynamic model for creep–fatigue behavior and damage evolution, International Journal of Fatigue, 2024, 184:108324
[160] Hongjiang Wang, Genghui Jiang, Weizhe Wang, Yingzheng Liu, A reduced-order configuration approach for the real-time calculation of three-dimensional flow behavior in a pipe network, Physics of Fluids, 2024, 36: 045127
[159] Han DONG, Han WANG, Zhenwei CAI, Weizhe Wang, Yingzheng LIU, Peridynamics–FEM coupling for interfacial delamination effected by vertical crack density in thermal barrier coatings, International Journal of Applied Mechanics, 2024, 16(1): 2450005-1-25
[158] Han Wang, Han Dong, Zhenwei Cai, Yingzhengliu ,Weizhe Wang, Fatigue behaviors of a nickel-based superalloy after hot-corrosion: experiments and peridynamic simulations, International Journal of Fatigue, 2024, 180: 108070-1-21
[157] Han WANG, Han DONG, Zhenwei CAI, Yingzheng LIU, Weizhe Wang, Peridynamic-based analysis on the fracture behaviors of the gas turbine blade, Engineering Fracture Mechanics, 2024, 295: 109817.
2023年論文
[156] Han DONG; Han WANG; Genghui JIANG; Zhenwei CAI; Weizhe Wang; Yingzheng LIU, An adaptive partitioned reduced order model of peridynamics for fast fracture simulation, Engineering Analysis with Boundary Elements, 2023, 157: 191-206
[155] Luyuan Ning, Zhenwei Cai, Han Dong, Yingzheng Liu, Weizhe Wang, Physics-informed neural network frameworks for crack simulation based on minimized peridynamic potential energy, Computer Methods in Applied Mechanics and Engineering, 2023, 417: 116430-1-20.
[154] Han Dong, Han Wang, Zhenwei Cai, Weizhe Wang, Yingzheng Liu, An enhanced adaptive coupling strategy of peridynamics and finite element method via variable horizon approach for simulating quasi-static fracture problems, Engineering Fracture Mechanics, 2023, 290: 109492-1-18.
[153] Genghui Jiang, Ming Kang, Zhenwei Cai, Han Wang, Yingzheng Liu, Weizhe Wang, Efficient reduced-order model for multiaxial creep–fatigue analysis based on a unified viscoplastic constitutive model, International Journal of Fatigue, 2023, 175: 107787-1-11
[152] Zhenwei Cai, Lijie Qiao, Xiaofeng Zhao, Weizhe Wang, Stress evaluation of TBCs with inclined film-cooling hole considering CMAS penetration-induced change of thermo-mechanical properties, Engineering Failure Analysis, 2023, 150: 107340-1-15.
[151]Han Wang, Han Dong, Zhenwei Cai, Yingzheng Liu, Weizhe Wang, Corrosion fatigue crack growth in stainless steels: A peridynamics-based numerical study, International Journal of Mechanical Sciences, 2023, 254: 108445-1-16
[150] Luyuan Ning, Lijie Qiao, Zhenwei Cai, Yingzheng Liu, Weizhe Wang, Elasticity-mechanics-informed generative adversarial networks for predicting the thermal strain of thermal barrier coatings penetrated by CaO–MgO–Al2O3–SiO2, European Journal of Mechanics - A/Solids, 2023, 100: 105027-1-13
[149] Ming Kang, Shifang Wu, Yingzheng Liu, Weizhe Wang, Viscoplastic model-based analysis of in-service oscillation temperature and thermal stress in a rotating component, International Journal of Thermal Sciences, 2023, 188: 108246-1-12
[148]Luyuan Ning, Zhenwei Cai, Han Dong, Yingzheng Liu, Weizhe Wang, A peridynamic-informed neural network for continuum elastic displacement characterization, Computer Methods in Applied Mechanics and Engineering, 2023, 407: 115909-1-24
[147]Han WANG, Zhenwei CAI, Han DONG, Yingzheng LIU, Weizhe Wang, Mechanical-chemical-coupled peridynamic model for the corrosion fatigue behavior of a nickel-based alloy, International Journal of Fatigue, 2023,168: 107400-1-16
2022年論文
[146] Han Wang, Han Dong, Zhenwei Cai, Yuhang Li, Weizhe Wang, Yingzheng Liu, Peridynamic-based investigation of the cracking behavior of multilayer thermal barrier coatings, Ceramics International, 48(16): 23543-23553, 2022
[145] Genghui Jiang, ChenhaoTan, Wenwei Jiang, Kai Yang, Weizhe Wang, Xiaowei Gao, Shape reconstruction in transient heat conduction problems based on radial integration boundary element method, International Journal of Heat and Mass Transfer, 2022, 191: 122830
[144]Genghui Jiang, Ming Kang, Zhenwei Cai, Han Wang, Yingzheng Liu, Weizhe Wang, Online reconstruction of 3D temperature field fused with POD-based reduced order approach and sparse sensor data , International Journal of Thermal Sciences, 175, 107489, 2022.
[143]Genghui Jiang, Ming Kang, Han Wang, Zhenwei Cai, Yingzheng Liu, Weizhe Wang, Data-driven temperature estimation of non-contact solids using deep-learning reduced-order models, International Journal of Heat and Mass Transfer, 185, 122383, 2022.
[142]Shifang Wu, Ming Kang, Zhenwei Cai, Weizhe Wang, Multi-axial creep-fatigue analysis of a cracked groove structure subjected to cyclic thermal loading, Engineering Failure Analysis, 131, 105826, 2022.
2021年論文
[141]Zhang, X., Shao, H., Zhou, W.., Wang, W. Z., and Liu, Y. A Comprehensive Heat Transfer Study Inside a Steam Turbine Valve: Experiment, Numerical Simulation, and Simplified Model, ASME. J. Eng. Gas Turbines Power. September 2021,143(9).
[140]ZhenWei Cai, Zi-Fan Zhang, Ying-Zheng Liu, Xiao-Feng Zhao , Weizhe Wang, Numerical Study on Effect of Non-Uniform CMAS Penetration on TGO Growth and Interface Stress Behavior of APS TBCs, Chinese Journal of Mechanical Engineering, 34:128, 2021.
[139]Luyuan Ning, Zhenwei Cai, Yingzheng Liu, Weizhe Wang, Conditional generative adversarial network driven approach for direct prediction of thermal stress based on two-phase material SEM images, Ceramics International, 47(24): 34115-34126, 2021.
[138]Luyuan Ning, Zhenwei Cai, Xiaofeng Zhao, Yingzheng Liu, Weizhe Wang, Fast Stress Evaluation of the Top Coat of Thermal Barrier Coatings under CaO–MgO–Al2O3–SiO2 Penetration Based on Image Recognition and an Artificial Neural Network, Ceramics International, 47(13), 18252-18261,2021
[137]Han WANG, Zhenwei CAI, Zifan ZHANG, Yingzheng LIU, Xiaofeng ZHAO, Weizhe Wang, Dynamic evolution of nonuniform temperature-stress distributions in continuously eroding thermal barrier coatings, Surface & Coatings Technology, 2021, 401, 126946 .
[136]R.A. Adjei, C.W. Fan, Weizhe Wang, Y.Z. Liu, Multidisciplinary Design Optimization for Performance Improvement of an Axial Flow Fan using Freeform Deformation, ASME Journal of Turbomachinery, Jan 2021, 143(1): 011003-1-18
[135]H. Hong, Z.W. Cai, Weizhe Wang, Y.Z. Liu, An Online Monitoring Method for Creep-Fatigue Life Consumption with Real-Time Damage Accumulation, International Journal of Damage Mechanics, 30(5) 764–785, 2021.
[134]Chen, W., Liu, Y., Wang, W., Zhao, X., Peng, D., 2021, “Interface detection in laser drilling of air plasma sprayed thermal barrier coatings by laser-induced breakdown spectroscopy”, Optics and Lasers in Engineering, vol.137, 106351.
[133] H Wang, ZW Cai, Weizhe Wang, YZ Liu, Peridynamic Simulation of Cracking Behavior in Thermal Barrier Coatings, the 14th International Conference on Damage Assessment of Structure, Shanghai, Oct.29-Nov.1, 2021 (Journal of Physics: Conference Series, 2184 (2022) 012045)
2020年論文
[132]H. Hong, Z.W. Cai, H. Wang, Weizhe Wang, Y.Z. Liu, A Model-Guided Neural Network for the Prediction of Creep Behavior under In-Service Conditions, ASME Journal of Engineering for Gas Turbines and Power, 2020, 142(7): 071008-18
[131]Z.W. Cai, H. Hong, X.F. Zhao, Weizhe Wang, Y.Z. Liu, Z.M. Cao, A numerical study of the influence of interface morphology on the stress behavior in thermal barrier coatings near an inclined-film cooling hole, Ceramics International, 2020, 46(11), 18142-18150
[130]Z.W. Cai, H. Hong, D. Peng, X.F. Zhao, Weizhe Wang, Y.Z. Liu, Z.M. Cao, Stress evolution in ceramic top coat of air plasma-sprayed thermal barrier coatings due to CMAS penetration under thermal cycle loading, Surface & Coatings Technology, 381(15), 2020, 125146
[129]J.S. Jiang, D.WU, W.Z. Wang, X.F. Zhao, X.F. Ma, B. Wang, H.J. Shi, Fracture behavior of TBCs with cooling hole structure under cyclic thermal loadings, Ceramics International, 3(46), 2020: 3644-3654
[128]T. Cai, ,S. Guo, Y. Li, D. Peng, X. Zhao, W.Z. Wang, Y.Z. Liu, Ultra-Sensitive Mechanoluminescent Ceramic Sensor based on Air-Plasma-Sprayed SrAl2O4:Eu2+, Dy3+ Coating, Sensors and Actuators A: Physical, 315, 2020:112246.
2019年論文
[127]H. Hong, Weizhe Wang, Y.Z. Liu, High-temperature fatigue behavior of a turbine rotor under flexible operating conditions with variable loading amplitudes, International Journal of Mechanical Sciences, 163, 2019, 105121
[126]R.A. Adjei, Weizhe Wang, Y.Z. Liu, Aerodynamic Design Optimization of an Axial Flow Compressor Stator Using Parameterized Free-Form Deformation, ASME JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER, 2019, 141(10): 101015
[125]Z.W. Cai, J.S. Jiang, Weizhe Wang, Y.Z. Liu, Z.M. Cao, CMAS penetration-induced cracking behavior in the ceramic top coat of APS TBCs, Ceramics International, 2019, 45(11), 14366-14375
[124]N.L. Zhao, Anish Roy,W.Z. Wang, Liguo Zhao,Vadim V. Silberschmidt, Coupling crystal plasticity and continuum damage mechanics for creep assessment in Cr-based power-plant steel, Mechanics of Materials, 2019, 130, 29-38.
[123]J.S. Jiang, L.X. Jiang, X.F. Zhao, Weizhe Wang, Y.Z. Liu, Z.M. Cao, Numerical stress analyses of the TBC-film cooling system under the operating condition considering the effects of thermal gradient and TGO growth, Surface & Coatings Technology, 2019, 357, 433-444
[122]Weizhe Wang, Y.Z. Liu, Continuum damage mechanics-based analysis of creep-fatigue-interaction behavior in a turbine rotor, International Journal of Damage Mechanics, 2019, 28(3), 455-477
[121]Fuqi Li, Bryan Quay, Peng Wang, Domenic A. Santavicca, Weizhe Wang, Sihua Xu, and Yingzheng Liu, Transient thermal behaviors of a scaled turbine valve: Conjugate heat transfer simulation and experimental validation, International Journal of Heat and Mass Transfer,2019, 141, 116-128
[120]Guo Songtao, Cai Tao, Zhao Xiaofeng, Peng Di, Xiao Ping, Wang Weizhe, Liu Yingzheng, Generalization of the quantitative stress-intensity relationship of mechanoluminescent sensor SrAl2O4:Eu2+,Dy3+ in elastic domain, Measurement Science and Technology,2019,30(7)
2018年論文
[119]Li, Y., Peng, D., Wang, W.Z., Liu, Y., Oouchida, S., Kawakubo, T., Yakushiji, A., Comparison of PSP and TSP Measurement Techniques for Fast Rotating Blades, AIAA Aviation 2018, AIAA 2018-3317.
[118]J.S. Jiang, X.F. Zhao, Weizhe Wang, Y.Z. Liu, Z.M. Cao, Numerical analyses of the residual stress and top coat cracking behavior in thermal barrier coatings under cyclic thermal loading, Engineering Fracture Mechanics, 2018, 196(1): 191-205
[117]J.S. Jiang, Z.H. Zou, Weizhe Wang, X.F. Zhao, Y.Z. Liu, Z.M. Cao, Effect of internal oxidation on the interfacial morphology and residual stress in air plasma sprayed thermal barrier coatings, Surface & Coatings Technology, 2018, 334(25):215-226
[116]B.Q. Xu, J.S. Jiang, Z.H. Zhou, W.Z. Wang, X.F. Zhao, Y.Z. Liu, P. Xiao, Time-dependent spalling behavior of thermally grown oxide induced by room temperature interfacial deformation, Surface & Coatings Technology, 2018, 334(25): 164-172
[115]J.S. Jiang, J.D. Yang, L. Xiao, S.H. Xu, Weizhe Wang, Y.Z. Liu, Numerical analysis of the impact effect of foreign bodies on a steam strainer in a steam turbine valve, Journal of Mechanical Science and Technology, 2018, 32 (1) :405-413
[114]N.L. Zhao, Weizhe Wang, Y.Z.Liu, Intergranular mechanical behavior in a blade groove-like component by crystal plasticity model with cohesive zone model, Engineering Fracture Mechanics, 2018, 201(1):196-213
[113]R.A. Adjei, Weizhe Wang, D. Peng, T. Bamba, Y.Z. Liu, Non-Uniform Tip Clearance Effects on Turbocharger Compressor Performance, Proceedings of ASME Turbo Expo, June 11-15, Norway, 2018
[112]Yifeng Hu, Gang Chen, Weizhe Wang, Investigation of Stress-Strain Behavior of a Component Under Variable Frequency Non-Proportional Loading, GT2018ASME Turbo Expo 2018 , June 11-15, 2018, Oslo, Norway
[111]Li Yongzeng, Peng Di, Wang Weizhe, Liu Yingzheng, Oouchida Satoshi, Kawakubo Tomoki, Yakushiji Akimitsu, Comparison of PSP and TSP measurement techniques for fast rotating blades, 34th AIAA Aerodynamic Measurement Technology and Ground Testing Conference, 2018, 2018-06-25 To 2018-06-29
2017年論文
[110]Weizhe Wang, S.H. Xu, Y.Z. Liu, Numerical investigation on creep-fatigue behavior in a steam turbine inlet valve under cyclic thermo-mechanical loading, ASME Journal of Engineering for Gas Turbines and Power, 2017, 139(11), 112502-112502-15.
[109]N.L. Zhao, Weizhe Wang, J.S. Jiang, Y.Z. Liu, Study of Creep-Fatigue Behavior in a 1000 MW Rotor Using a Phenomenological Lifetime Model, Journal of Mechanical Science and Technology, 2017, 31(2): 605-614.
[108]J.S. Jiang, B.Q. Xu, Weizhe Wang, Richard Adjei, X.F. Zhao, Y.Z. Liu, Finite Element Analysis of the Effects of Thermally Grown Oxide Thickness and Interface Asperity on the Cracking Behavior Between the Thermally Grown Oxide and the Bond Coat, ASME Journal of Engineering for Gas Turbines and Power, 2017, 139: 022504-1-9.
[107]Z.W. Cai, Weizhe Wang, H. Hong, R5 Code Based Creep Analysis of a Thick-Wall Cylinder With Steam Film Cooling Hole Structure, ASME PVP July 16-20, USA, 2017
[106]J.S. Jiang, Z.W. Cai, Weizhe Wang, Y.Z. Liu, Finite element analysis of thermal-mechanical behavior in the thermal barrier coatings with cooling holes structure, Proceedings of ASME Turbo Expo, June 26-30, USA, 2017
[105]R. A. Adjei, Weizhe Wang, J.S. Jiang, Y.Z. Liu, T. Kawakubo, Numerical investigation of unsteady shock wave motion in a transonic centrifugal compressor, Proceedings of ASME Turbo Expo, June 26-30, USA, 2017
2016年論文
[104]Weizhe Wang, P. Buhl, A. Klenk, Y.Z. Liu, A continuum damage mechanics-based viscoplastic model of adapted complexity for high temperature creep-fatigue loading, ASME Journal of Engineering for Gas Turbines and Power, 2016, 138(9), 092501-10.
[103]Weizhe Wang, P. Buhl, A. Klenk, Y.Z. Liu, The effect of in-service steam temperature transients on the damage behavior of a steam turbine rotor, International Journal of Fatigue, 2016,87, 471–483.
[102]Weizhe Wang, P. Buhl, A. Klenk, Y.Z. Liu, Influence of high-temperature dwell time on creep-fatigue behavior in a 1000 MW steam turbine rotor, Engineering Fracture Mechanics, 2016, 166, 1-22.
[101]Weizhe Wang, P. Buhl, A. Klenk, Y.Z. Liu, Study of creep-fatigue behaviour in a 1000 MW rotor using a unified viscoplastic constitutive model with damage, International Journal of Damage Mechanics;25(2): 178-202, 2016
[100]N.L. Zhao, Weizhe Wang, J.H. Zhang, Y.Z. Liu, Numerical investigation on life improvement of low-cycle fatigue for an ultra-supercritical steam turbine rotor, Journal of Mechanical Science and Technology, 2016, 30(4), 1747-1754
[99]N.L. Zhao, Weizhe Wang, H. Hong, Richard Adjei, Y.Z. Liu, Mechanical behavior study of steam turbine casing bolts under in-service conditions, ASME TURBO EXPO 2016
[98]H. Hong, Weizhe Wang, N.L. Zhao, Z.W. Cai, Y.Z. Liu, Influence of temperature and pressure fluctuation on the mechanical behavior of a seal structure in steam turbine valve under in-service condition, ASME TURBO EXPO 2016
[97]Z.W. Cai, Weizhe Wang , Y.Z. Liu, R5 procedure based damage estimation in a steam turbine valve under in-service conditions, ASME Pressure Vessels and Piping, Canada, Vancouver, 2016
[96]H. Hong, Weizhe Wang , Y.Z. Liu, Fatigue life investigation of a high pressure inner casing under in-service conditions, ASME Pressure Vessels and Piping, Canada, Vancouver, 2016
[95]Z.W. Cai, Weizhe Wang, Y.Z. Liu, Numerical study of steam film cooling behavior in a thick-wall cylinder, 9th China-Japan Bilateral Symposium on High Temperature Strength of Materials, Changsha, China, 2016.
[94]Richard A. Adjei, Weizhe Wang, Nailong Zhao, Yingzheng Liu,Fatigue and lifetime estimation of a highly stressed centrifugal compressor impeller(分組特邀報(bào)告),第十八屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議, 2016
2015年論文
[93]Weizhe Wang, Y.Z. Liu, Analysis of the sealing performance and creep behavior of the inner casing of a 1000 MW supercritical steam turbine under bolt relaxation, Engineering Failure Analysis, 57: 363-376, 2015
[92]Weizhe Wang, Y.Z. Liu, P.N. Jiang, Numerical investigation on influence of real gas properties on nonlinear behavior of labyrinth seal-rotor system, Applied Mathematics and Computation, 263: 12-24, 2015
[91]Weizhe Wang, P. Buhl, A. Klenk , A unified viscoplastic constitutive model with damage for multi-axial creep-fatigue loading, International Journal of Damage Mechanics, 24(3): 363-382, 2015
[90]J.S. Jiang, Weizhe Wang , Y.Z. Liu, Application of a creep-damage constitutive model for the rotor of a 1000 MW ultrasupercritical steam turbine, ASME Journal of Engineering for Gas Turbines and Power, 2015, 138(2):022606-022606-6
[89]J.F. Mao, Weizhe Wang, J.H. Zhang, Y.Z. Liu, Numerical investigation on the dynamic behaviors of turbine valve disc–seat impact at low velocity, Journal of Mechanical Science and Technology, 29(2):1-9, 2015
[88]G.C. Jiao, Weizhe Wang, S.J. Tan, C. Yu, Y.Z. Liu, Crack-tip constraint analysis of SENB specimen under creep condition, Journal of Mechanical Science and Technology, 29 (2):1-6, 2015
[87]Z.W. Cai, Weizhe Wang , Study of Creep Damage of a Thin-wall Outer Casing of a 1000MW Ultra-supercritical Steam Turbine, The 13th Asian International Conference on Fluid Machinery, 7th-10th Sept., WASEDA University, Tokyo, Japan, 2015
[86]H. Hong, Weizhe Wang , Numerical Investigation of Creep Behavior of an Inner Casing of a 1000MW Ultra-supercritical Steam Turbine, The 13th Asian International Conference on Fluid Machinery, 7th-10th Sept., WASEDA University, Tokyo, Japan, 2015
[85]J.S. Jiang, Weizhe Wang , Y.Z. Liu, Application of a creep damage constitutive model for the rotor of a 1000 MW ultra-supercritical steam turbine, ASME Journal of Engineering for Gas Turbines and Power, ASME TURBO EXPO 2015, Montreal, Canada, 2015
2014年論文
[84]Weizhe Wang, Analysis of multi-axial creep-fatigue damage on an outer cylinder of a 1000MW supercritical steam turbine, ASME Journal of Engineering for Gas Turbines and Power, 136(11): 112504-112504-8, 2014
[83]Weizhe Wang, Numerical analysis of fatigue life improvement by optimizing the startup phase for a 1000 MW supercritical steam turbine inner casing, ASME Journal of Engineering for Gas Turbines and Power, 137(4):042601-042601-10, 2014
[82]Weizhe Wang, J.H. Zhang, Influence of creep on low-cycle fatigue life assessment of ultra-supercritical steam turbine rotor, ASME TURBO EXPO 2014, June 16-20, Dusseldorf, Germany, 2014
[81]Weizhe Wang, Chao Yu, Junhui Zhang, Yingzheng Liu, Numerical investigation on creep and fatigue behavior of a 1000 MW steam turbine inner cylinder [C. International Conference on Fatigue Damage of Structural Material X, The Resort and Conference Center at Hyannis, MA, USA, 21-26 September 2014
[80]J.F. Mao, Weizhe Wang, Y.Z. Liu, J.H. Zhang, Comparative study of flange-to-seal contact couplings with bolt relaxation under creep condition, ASME Journal of Engineering for Gas Turbines and Power, 136(7):072504-072504-8, 2014
[79]J.F. Mao, W.Z. Wang, Environmental fatigue analysis of a U seal in pressure vessel under simulated LWR operation, Engineering Failure Analysis, 36: 362-371, 2014
2013年以前發(fā)表論文.
[78]Mao Jianfeng, Zhang Junhui, Weizhe Wang, The multiaxial creep strength analysis coupling with damage evolution for 3D innercasing of the USC turbine system, 2nd International Conference on Materials Science and Engineering, ICMSE 2013, 2013-03-08 To 2013-03-10.
[77]Jianfeng Mao, Junhui Zhang, Weizhe Wang, Yingzheng Liu, Creep-Fatigue Life Prediction of Stop and Regulating Valves on the Intermediate-Pressure Section of a 1000MW Steam Turbine, GT2013 ASME Turbo Expo 2013, June 3-7, 2013, San Antonio, Texas, USA
[76]J.F. Mao, Weizhe Wang, Y.Z. Liu, Experimental and theoretical investigation on the sealing performance of the combined seals for reciprocating rod, Journal of Mechanical Science and Technology, 26(6): 1765-1772, 2012
[75]P.N. Jiang, Weizhe Wang, Y.Z. Liu, G. Meng, Influence of steam leakage through vane, gland, and shaft seals on rotordynamics of high-pressure rotor of a 1,000 MW ultra-supercritical steam turbine, Archive of Applied Mechanics, 82(2): 177-189, 2012
[74]G.C. Jiao, Weizhe Wang, Crack-tip constraint analysis of two collinear cracks under creep condition, Structural Engineering and Mechanics, 43(3): 311-320, 2012
[73]J.F. Mao, Weizhe Wang, Y.Z. Liu, J.H. Zhang, Multiaxial creep-fatigue life prediction on the rotor of a 1000MW supercritical steam turbine, GT-2012 ASME Turbo Expo, Copenhagen, Denmark, June 11-15, 2012
[72]G.C. Jiao, G. Chen, Weizhe Wang, A model to predict the stress corrosion cracking growth rate of the metallic materials, GT-2012 ASME Turbo Expo, Copenhagen, Denmark, June 11-15, 2012
[71]P.N. Jiang, Weizhe Wang, G.C. Jiao, Analysis of high temperature creep on the nut connection components of a 600MW supercritical steam turbine, GT-2012 ASME Turbo Expo, Copenhagen, Denmark, June 11-15, 2012
[70]Weizhe Wang , Ying Zheng Liu, Guang Meng, Pu Ning Jiang, Influence of rub groove on rotordynamics associated with leakage air flow through a labyrinth seal, Journal of Mechanical Science and Technology, 2010,24(8):1573-1581, 2010.04
[69]Yu Jun, Shi Liu liu, Wang Wei zhe, Liu Ying zheng, CONDITIONAL AVERAGING OF TR-PIV MEASUREMENTS OF WAKE BEHIND SQUARE CYLINDER USING AN IMPROVED CROSS-CORRELATION APPROACH, Journal of Hydrodynamics, 2010, 22(1): 29-34.
[68]Weizhe Wang, LIU Ying-zheng, Meng Guang, Jiang Pu-ning, A nonlinear model of flow-structure interaction between steam leakage through labyrinth seal and the whirling rotor, Journal of Mechanical Science and Technology, 2009(23): 3302-3315.
[67]Weizhe Wang, LIU Ying-zheng, JIANG Pu-ning, CHEN Han-ping, Nonlinear analysis of orbital motion of the rotor subject to leakage air flow through an interlocking seal, Journal of Fluids and Structures, 2009,2 (DOI: 10.1016/j.jfluidstructs.2008.07.009)
[66]Wang Qing, Wang Weizhe, Fei Zhi-min, Liu Ying-zheng, Cao Zhao-min, SIMULATION OF BLOOD FLOW IN INTRACRANIAL ICA-PCOMA ANEURYSM VIA COMPUTATIONAL FLUID DYMAMICS MODELING, Journal of Hydrodynamics, 2009, 21(5): 583-590
[65]Weizhe Wang, LIU Ying-zheng, CHEN Han-ping, et al., Computation of Rotordynamic Coefficients Associated with Leakage Steam Flow through Labyrinth Seal, Archive of Applied Mechanics, Archive of Applied Mechanics, 2007, 77(8): 587-597.
[64]LIU Ying-zheng, W.Z. Wang, Chen Han-ping, .Jing Jian-ping, GE Qing, YUAN Ying, Influence of leakage flow through labyrinth seals on rotordynamics: numerical calculations and experimental measurements, Archive of Applied Mechanics, Archive of Applied Mechanics, 2007, 77(8): 599-612.
[63]Weizhe Wang, LIU Ying-zheng, JIANG Pu-ning CHEN Han-ping, Numerical analysis of leakage flow through two labyrinth seals, Journal of Hydrodynamics Ser.B, 2007, 19(1): 107-112.
[62]Liu Ying zheng, Ke Feng, Wang Wei zhe, Cao Zhao min, PRESSURE-VELOCITY JOINT MEASUREMENTS OF A WALL-BOUNDED TURBULENT SHEAR FLOW, Journal of Hydrodynamics, 2006, 18(3): 315-318.
[61]Ke Feng, Liu Ying zheng, Jin Chun yu, Wang Weizhe, EXPERIMENTAL MEASUREMENTS OF TURBULENT BOUNDARY LAYER FLOW OVER A SQUARE-EDGED RIB,Journal of Hydrodynamics, 2006, 18(3): 461-464.
[60]Ke Feng, Liu Ying zheng, Wang Weizhe, Chen Han ping, WALL PRESSURE FLUCTUATIONS OF TURBULENT FLOW OVER BACKWARD-FACING STEP WITH AND WITHOUT ENTRAINMENT: MICROPHONE ARRAY MEASUREMENT, Journal of Hydrodynamics, 2006, 18(4): 393-396.
[59]Jin Si yu, Liu Ying zheng, Wang Weizhe, Cao Zhao min, Koyama Hide S, NUMERICAL EVALUATION OF TWO-FLUID MIXING IN A SWIRL MICRO-MIXER, Journal of Hydrodynamics, 2006, 18(5): 542-546.
[58]Weizhe Wang, LIU Ying-zheng, Meng Guang, A Nonlinear Model of Rotor-Bearing-Seal System Associated With Leakage Through the Labyrinth Seal, GT2010-Proceedings of ASME Turbo Expo 2010: Power for Land, Sea and Air, June 14-18, 2010, Glasgow, UK
[57]Weizhe Wang, LIU Yingzheng, CHEN Hanping, et al. Numerical and Experimental Investigation of Labyrinth-Seal Flow and Rotor Dynamics, AICFM-9, Jeju, Korea, 2007, 10.
[56]Ke Feng, Liu Ying zheng, Jin Chun yu, Wang Wei zhe,Experimental measurements of turbulent boundary layer flow over a square-edged rib,Conference on Global Chinese Scholars on Hydrodynamics, 2006-07-11 To 2006-07-14.
【中文論文】.
[55]張子凡,韓彥冬,王煒哲,蔡振威,CMAS 滲透下熱障涂層界面失效分析,航空動(dòng)力學(xué)報(bào),2021,36(8):1702-1711
[54]陳強(qiáng)強(qiáng),吳仕芳,康明,洪輝,蔡振威,王煒哲,汽輪機(jī)高壓缸金屬塊接觸密封蠕變強(qiáng)度與蠕變變形分析,中國(guó)電機(jī)工程學(xué)報(bào), 2021,41(7):2455-2462
[53]羅淇元,韓彥冬,蔡振威,王煒哲, 基于NARX神經(jīng)網(wǎng)絡(luò)的汽輪機(jī)轉(zhuǎn)子溫度變化趨勢(shì)實(shí)時(shí)預(yù)測(cè),熱能動(dòng)力工程,2021,36(7):39-45
[52]張子凡,蔡振威,王煒哲,彭迪,劉應(yīng)征,循環(huán)熱力載荷下含冷卻孔熱障涂層的強(qiáng)度分析,湘潭大學(xué)學(xué)報(bào)(自然科版), 2019,41(6):104~112
[51]蔡振威,洪輝,王煒哲,劉應(yīng)征,CMAS滲透對(duì)APS熱障涂層應(yīng)力及開裂的影響,第九屆國(guó)際稀土開發(fā)與應(yīng)用研討會(huì)暨2019中國(guó)稀土學(xué)會(huì)學(xué)術(shù)年會(huì),2019
[50]王煒哲,蔡振威,洪輝,彭迪,劉應(yīng)征,復(fù)雜載荷下含冷卻孔APS熱障涂層的結(jié)構(gòu)強(qiáng)度分析,第九屆國(guó)際稀土開發(fā)與應(yīng)用研討會(huì)暨2019中國(guó)稀土學(xué)會(huì)學(xué)術(shù)年會(huì),2019
[49]牛鵬坤,洪輝,王煒哲,基于改進(jìn)遺傳算法的電站鍋爐效率優(yōu)化,熱能動(dòng)力工程,2020,35(3):111-115
[48]周覺,蔡振威,王煒哲,基于R5規(guī)范的超超臨界汽輪機(jī)閥門損傷評(píng)估,動(dòng)力工程學(xué)報(bào),2019,39(09):705-710,724
[47]蔣凌欣,蔣季伸,王煒哲,體積輻射換熱對(duì)熱障涂層—?dú)饽だ鋮s系統(tǒng)中涂層溫度場(chǎng)的影響,動(dòng)力工程學(xué)報(bào),2019,39(06):441-446
[46]陳詩(shī)坤,王鵬,蔡振威,洪輝,王煒哲,定參數(shù)快速冷啟動(dòng)過(guò)程中主汽-調(diào)節(jié)閥結(jié)構(gòu)強(qiáng)度分析及優(yōu)化,動(dòng)力工程學(xué)報(bào),2019,39(05):360-365,372
[45]趙乃龍,王煒哲,主蒸汽溫度和壓力波動(dòng)對(duì)汽輪機(jī)轉(zhuǎn)子蠕變疲勞損傷的影響,上海交通大學(xué)學(xué)報(bào),2019,53(02),127-133
[44]王煒哲,劉應(yīng)征,蠕變-疲勞-損傷耦合行為本構(gòu)模型及其在汽輪機(jī)高溫轉(zhuǎn)子中的應(yīng)用,第十九屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,沈陽(yáng),2018.8.15-17(邀請(qǐng)報(bào)告)
[43]洪輝,王煒哲,高溫蠕變下裂紋干涉對(duì)損傷行為的影響研究,第十九屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,沈陽(yáng),2018.8.15-17
[42]蔣季伸,王煒哲,劉應(yīng)征,高溫環(huán)境下熱障涂層-氣膜冷卻系統(tǒng)的應(yīng)力分析,第十九屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,沈陽(yáng),2018.8.15-17
[41]蔡振威,王煒哲,劉應(yīng)征,不同冷卻速率對(duì)TRISO 核燃料多層結(jié)構(gòu)強(qiáng)度影響的研究,高第十九屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,沈陽(yáng),2018.8.15-17
[40]蘇虎,王煒哲等,啟停運(yùn)行工況下超超臨界機(jī)組高壓缸平衡活塞區(qū)域結(jié)構(gòu)強(qiáng)度與間隙變化分析,動(dòng)力工程學(xué)報(bào),2018,38(09):713-718,731
[39]朱東曉,王煒哲,水蒸氣黏性對(duì)非接觸式指尖密封動(dòng)壓靴熱變形的影響分析,動(dòng)力工程學(xué)報(bào),2017,8:622-628
[38]蔡振威,王煒哲,胡怡豐 ,劉應(yīng)征,優(yōu)化啟動(dòng)溫升率對(duì)汽輪機(jī)中壓薄壁外缸疲勞行為的影響,第十八屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議, 2016
[37]趙乃龍,王煒哲,劉應(yīng)征,現(xiàn)場(chǎng)服役機(jī)組蒸汽溫度波動(dòng)對(duì)汽輪機(jī)轉(zhuǎn)子蠕變-疲勞損傷的影響,第十八屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議, 2016
[36]蔣季伸,王煒哲,冷卻孔附近熱障涂層應(yīng)力分析,第十一屆全國(guó)表面工程大會(huì)暨第八屆全國(guó)青年表面工程學(xué)術(shù)會(huì)議,10/22-25,成都,中國(guó)
[35]蔣季伸,王煒哲,劉應(yīng)征,冷卻孔附近熱障涂層的應(yīng)力及失效機(jī)理分析,2016中國(guó)工程熱物理年會(huì),11/9-12,廣州,中國(guó)
[34]趙乃龍,吳穹,王煒哲,張軍輝. 超超臨界汽輪機(jī)高壓轉(zhuǎn)子低周疲勞及損傷分析, 上海交通大學(xué)學(xué)報(bào),2015, 49(5): 590-594.
[33]吳穹,王煒哲,張軍輝,胡怡豐,高清輝. 超超臨界汽輪機(jī)中壓轉(zhuǎn)子高溫蠕變強(qiáng)度分析,動(dòng)力工程學(xué)報(bào),2015, 35(1):25-29.
[32]喻超,王煒哲,陳鋼,核電汽輪機(jī)低壓焊接轉(zhuǎn)子熱處理殘余應(yīng)力的數(shù)值分析,動(dòng)力工程學(xué)報(bào),2014,34(01) :19-24,31
[31]喻 超,王煒哲,張軍輝,劉應(yīng)征,超超臨界機(jī)組高壓內(nèi)缸蠕變強(qiáng)度分析,動(dòng)力工程學(xué)報(bào),2014,34(05):365-370
[30]毛劍峰,張軍輝,王煒哲,陳漢平,汽輪機(jī)進(jìn)汽閥U型密封高溫強(qiáng)度與密封性能分析. 中國(guó)電機(jī)工程學(xué)報(bào),2013,33(20): 104-110,18.
[29]毛劍峰,王煒哲,張軍輝,超超臨界汽缸高溫強(qiáng)度及多軸蠕變分析,力學(xué)季刊,2013,34(3):437-443.
[28]焦廣臣,王煒哲,蔣蒲寧,劉應(yīng)征,核電汽輪機(jī)轉(zhuǎn)子結(jié)構(gòu)應(yīng)力腐蝕裂紋擴(kuò)展研究,汽輪機(jī)技術(shù),2013,55(2):113-114.
[27]談尚炯,陳鋼,焦廣臣,王煒哲,陳漢平,噴丸對(duì)紅套轉(zhuǎn)子應(yīng)力腐蝕失效概率的影響,熱力透平,2013,42(03):181-185.
[26]談尚炯,王煒哲,陳漢平,劉應(yīng)征,汽輪機(jī)復(fù)雜套裝轉(zhuǎn)子內(nèi)部應(yīng)力分析,動(dòng)力工程學(xué)報(bào),2013, 33(08):581-585.
[25]毛劍峰,王煒哲,劉應(yīng)征,陳漢平,汽輪機(jī)螺栓松弛對(duì)汽缸蠕變強(qiáng)度的影響,動(dòng)力工程,2013,33(2):107-111.
[24]陳鋼, 蔣浦寧, 王煒哲,焦廣臣, 汽輪機(jī)部件應(yīng)力腐蝕壽命評(píng)估方法研究,熱力透平, 2012, (03): 179-182,219
[23]焦廣臣,王煒哲,馬春雷,孫乃杰,基于斷裂力學(xué)的核電結(jié)構(gòu)完整性評(píng)估的數(shù)值工具,第16屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,2012.
[22]毛劍峰,王煒哲,張軍輝,劉應(yīng)征,高參數(shù)中壓內(nèi)缸高溫強(qiáng)度及多軸蠕變分析,第16屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,2012
[21]戴偉,王煒哲,劉應(yīng)征,徑向間隙對(duì)刷式密封泄漏特性影響的數(shù)值分析.動(dòng)力工程學(xué)報(bào),2011,7(31):507-512
[20]劉華鋒,王煒哲,蔣浦寧,劉應(yīng)征, 陳漢平,超超臨界汽輪機(jī)轉(zhuǎn)子蠕變對(duì)低周疲勞應(yīng)變的影響,動(dòng)力工程,2010,30(09): 715-719
[19]王煒哲,蔣浦寧,張軍輝,劉應(yīng)征,陳漢平,非比例拉扭組合循環(huán)加載下扭轉(zhuǎn)載荷幅對(duì)構(gòu)件應(yīng)力影響的數(shù)值分析,中國(guó)動(dòng)力工程學(xué)會(huì)透平專業(yè)委員會(huì)2010年學(xué)術(shù)研討會(huì),2010.10
[18]焦廣臣, 王煒哲, 蔣浦寧, 劉應(yīng)征, 陳漢平, 當(dāng)?shù)貞?yīng)力狀況對(duì)應(yīng)力腐蝕裂紋起始?jí)勖挠绊懛治?/span>, 第十五屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,2010.11
[17]王煒哲,焦廣臣,張軍輝,劉應(yīng)征,陳漢平,非比例加載下扭轉(zhuǎn)載荷頻率對(duì)構(gòu)件力學(xué)行為影響的數(shù)值分析,第十五屆全國(guó)疲勞與斷裂學(xué)術(shù)會(huì)議,2010.11
[16]鄔文睿,王煒哲,蔣浦寧,劉應(yīng)征,陳漢平,660MW超超臨界汽輪機(jī)高壓轉(zhuǎn)子的高溫蠕變強(qiáng)度分析,動(dòng)力工程,2009, 29(2):99-103
[15]王青,王煒哲,萬(wàn)大偉,費(fèi)智敏,劉應(yīng)征,曹兆敏,三例人體頸動(dòng)脈分叉管血液動(dòng)力學(xué)的數(shù)值對(duì)比分析, 水動(dòng)力學(xué)研究與進(jìn)展:A輯,2009 ,24(3):313-318.
[14]林文進(jìn),王煒哲,劉應(yīng)征,陳漢平,風(fēng)室試驗(yàn)中軸對(duì)稱排氣引射-混合器的引射特性,上海交通大學(xué)學(xué)報(bào),2009,43(05): 759-762,771
[13]鄔文睿,王煒哲,蔣浦寧,劉應(yīng)征,陳漢平,660MW超超臨界汽輪機(jī)高壓轉(zhuǎn)子高周疲勞強(qiáng)度分析, 中國(guó)動(dòng)力工程學(xué)會(huì)第四屆青年學(xué)術(shù)年會(huì),北京,2009.01.
[12]鄔文睿,王煒哲,劉華鋒,劉應(yīng)征,660MW超超臨界汽輪機(jī)高壓轉(zhuǎn)子蠕變疲勞耦合分析,2009先進(jìn)電站用耐熱鋼與合金國(guó)際研討會(huì),2009.10-21-24,上海.
[11]焦廣臣,王煒哲,劉華鋒,具有不同裂紋尺寸的三維裂紋試件裂紋端的高溫蠕變研究,2009先進(jìn)電站用耐熱鋼與合金國(guó)際研討會(huì),2009.10-21-24,上海.
[10]鄔文睿,王煒哲,劉華鋒,劉應(yīng)征,660MW超超臨界汽輪機(jī)高壓轉(zhuǎn)子低周疲勞強(qiáng)度分析,中國(guó)力學(xué)學(xué)會(huì)2009學(xué)術(shù)大會(huì),2009.08
[9]王煒哲,鄔文睿,劉應(yīng)征,陳漢平,數(shù)值分析交錯(cuò)齒密封結(jié)構(gòu)對(duì)密封性能的影響,中國(guó)工程熱物理學(xué)會(huì)2008年流體機(jī)械學(xué)術(shù)會(huì)議,2008
[8]鄔文睿, 萬(wàn)津津, 王煒哲, 劉應(yīng)征, 600MW亞臨界機(jī)組主調(diào)閥蒸汽流動(dòng)損失數(shù)值分析, 水動(dòng)力學(xué)研究與進(jìn)展A輯, 2008, (05).
[7]王煒哲, 劉應(yīng)征, 陳漢平等.汽輪機(jī)軸封-轉(zhuǎn)子系統(tǒng)動(dòng)力學(xué)特性的數(shù)值分析,動(dòng)力工程,2007,27(6):845-849 .
[6]王煒哲, 劉應(yīng)征, 陳漢平等. 迷宮密封—轉(zhuǎn)子系統(tǒng)動(dòng)力學(xué)特性的試驗(yàn)測(cè)量和數(shù)值模擬,機(jī)械工程學(xué)報(bào),2007,43(3): 22-27.
[5]王煒哲, 劉應(yīng)征, 陳漢平等. 迷宮軸封氣流周向剪切力對(duì)轉(zhuǎn)子動(dòng)態(tài)特性系數(shù)的影響,動(dòng)力工程,2007,27(5): 717-720
[4]王煒哲,施鎏鎏,劉應(yīng)征等. 1000MW超臨界汽輪機(jī)主調(diào)閥內(nèi)流動(dòng)和噪聲計(jì)算分析,動(dòng)力工程,2007,27(3): 401-405
[3]韋康, 葉春, 葛誦,王煒哲, 劉應(yīng)征, 忻建華,氣隙激振力對(duì)轉(zhuǎn)子臨界轉(zhuǎn)速的影響,動(dòng)力工程學(xué)報(bào), 2006, (01): 6-9.
[2]陳獻(xiàn)春,楊俊, 周宇陽(yáng), 王煒哲, 陳廣兵, 董軍,基于DCS一體化的球磨機(jī)制粉系統(tǒng)仿真建模,熱力發(fā)電,2005, (01): 40-42,60.
[1]王煒哲,周宇陽(yáng),陳漢平,基于圖形組態(tài)的可壓縮流體網(wǎng)絡(luò)仿真模型,汽輪機(jī)技術(shù),2003,6:358-360
軟件版權(quán)登記及專利
專利軟件
1.專利軟件名稱:密封結(jié)構(gòu)參數(shù)管理軟件, 授權(quán)號(hào):2009SR050154
2.專利軟件名稱:空壓機(jī)內(nèi)密封泄漏流動(dòng)分析軟件, 授權(quán)號(hào):2009SR050163
3.專利軟件名稱:密封系統(tǒng)非線性轉(zhuǎn)子動(dòng)力學(xué)分析軟件, 授權(quán)號(hào):2009SR050167
4.專利軟件名稱:氣流激振力分析軟件, 授權(quán)號(hào):2009SR049996
5.專利軟件名稱:密封泄漏分析軟件, 授權(quán)號(hào):2009SR050165
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專利
1.袁鷹; 金永明; 蔣浦寧; 劉應(yīng)征; 柯峰; 王煒哲, 動(dòng)態(tài)壓力傳感器在線標(biāo)定連接裝置, 2006-10-11, 中國(guó), ZL200520041732.1.
2.自抑制泄漏的密封結(jié)構(gòu)形式,專利號(hào):ZL 2012 2 0497548.8
3.自抑制有效通流面積的齒形結(jié)構(gòu),專利號(hào):ZL 2012 2 0498041.4
4.齒頂間隙局部增阻密封齒形結(jié)構(gòu),專利號(hào):ZL 2012 2 0498052.2
5.彭迪; 陳佳偉; 郭仲秋; 王煒哲; 劉應(yīng)征, 一種基于AAO模板的柔性快響應(yīng)PSP測(cè)試裝置、方法與應(yīng)用, 2017-08-17, 中國(guó), CN201710707848.1
6. 基于降階模型的瞬態(tài)熱力狀態(tài)在線評(píng)估方法、設(shè)備及介質(zhì),中國(guó),2024-2-13,授權(quán)公告號(hào):CN 113722860 B
7. 多相復(fù)合結(jié)構(gòu)圖像的載荷狀態(tài)快速評(píng)估方法及設(shè)備,申請(qǐng)?zhí)枺?02210471459.4
8. 一種基于FPGA集成降階模型的流動(dòng)狀態(tài)在線監(jiān)測(cè)系統(tǒng)及方法,申請(qǐng)?zhí)枺?02310530402.1
9. 一種基于降階組態(tài)的管網(wǎng)三維流動(dòng)在線預(yù)測(cè)方法,申請(qǐng)?zhí)枺?02410221826.4
10. 一種基于數(shù)字孿生感知框架的狀態(tài)監(jiān)測(cè)和故障診斷方法,中國(guó),授權(quán)公告號(hào):CN 119514284 B
2025, 中國(guó)電力發(fā)展促進(jìn)會(huì)科學(xué)技術(shù)獎(jiǎng)(二等獎(jiǎng),數(shù)智電力),“重型燃機(jī)熱端部件跨尺度量化評(píng)估與長(zhǎng)壽命調(diào)控技術(shù)及應(yīng)用”
2025,中國(guó)華電集團(tuán)有限公司科學(xué)技術(shù)獎(jiǎng)(二等獎(jiǎng)),“燃機(jī)熱端部件多物理場(chǎng)強(qiáng)度評(píng)估與服役保障技術(shù)及應(yīng)用”
2024,上海產(chǎn)學(xué)研合作優(yōu)秀項(xiàng)目
2023,國(guó)際會(huì)議DACOMA-23(Data-driven Computing and Machine Learning in Engineering 2023)學(xué)生最佳演講獎(jiǎng)指導(dǎo)老師
2022,學(xué)院優(yōu)秀碩士論文
2018,上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院“最受歡迎畢業(yè)生導(dǎo)師"
2015,年度考核優(yōu)秀
2011,新進(jìn)青年教師啟動(dòng)計(jì)劃
2010,SMC-晨星優(yōu)秀青年教師
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