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& k: z: }1 `/ ]5 T/ C崔向阳 (湖南大学机械与运载工程学院教授) [url=]编辑[/url] 本词条缺少概述图,补充相关内容使词条更完整,还能快速升级,赶紧来[url=]编辑[/url]吧!) ~9 }) Y9 ]2 s: L3 i; ]
崔向阳,男,博士,湖南大学机械与运载工程学院教授、博士生导师。 [1]- Q4 z, E! P5 M& \' X8 H
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) d8 E$ v0 ]% c1 V中文名崔向阳毕业院校湖南大学学位/学历博士专业方向机械与运载工程学任职院校湖南大学2 f3 j7 q& e% [( k! p( R( ?' M
目录- ▪ 参与项目
4 学术成果3 O) H! O! Z- Q- U7 \: _
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6 H2 v w$ V: H: h人物经历[url=]编辑[/url]
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教育经历
$ a. d( z; \+ w* {9 p8 R" M( Q2009.8-2011.9 湖南大学汽车车身先进设计制造国家重点实验室,博士研究生3 j0 g: p) a8 n+ A( ]0 @" H2 L8 D
2007.8-2009.8 新加坡国立大学机械工程系,联合培养博士生
6 y. |8 p0 L8 J0 s2005.9-2007.8 湖南大学汽车车身先进设计制造国家重点实验室,硕士研究生) N9 C& M- S0 G, \$ w$ O* \
2001.9-2005.7 湖南大学机械与汽车工程学院,机械设计制造及其自动化专业,本科 [1]& i' W+ X- Z+ a( Y* B# l% M! e
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工作经历, E' z" l2 f& W. s( b
2009.10-2012.11 湖南大学机械与汽车工程学院/汽车车身先进设计制造国家重点实验室,讲师* B" w/ ]) d5 I2 L* v
2012.12-2019.01 湖南大学机械与汽车工程学院/汽车车身先进设计制造国家重点实验室,副教授0 I* s: m- j, L1 G
2019.01-今 湖南大学机械与汽车工程学院/汽车车身先进设计制造国家重点实验室,教授
, q) O/ L5 B# L8 }9 Q' O3 Q- u2017.09-今 汽车车身先进设计制造国家重点实验室,副主任 [1]
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学术兼职
1 W. V2 I: c; k2 L* d+ N0 ]5 ^% ]- D国际杂志 “International Journal of Computational Methods”,Guest editor
3 K+ d' _$ N7 Y% p9 d( C( C7 g3 y国际杂志 “PLOS ONE”,Academic Editor
6 ]2 H) U9 x1 B$ L( M% ?6 t% h国际会议 “The 5th Asia Pacific Congress on Computational Mechanics (APCOM 2013)”,“Smoothed Finite Element Methods”分会场主席
7 A8 C4 O. H% s0 W3 F9 l国际会议“The 7th International Conference on Computational Methods (ICCM2016)”,“Computational Methods in Engineering”分会场主席
* j9 M" L3 l. m. X% `国际会议 “The 7th International Conference on Computational Methods(ICCM2016)”,分会场主席 [1]) ~* @3 ]+ Y+ L
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学科领域:车辆工程,机械设计及理论,材料成形,计算力学, [* D$ `) h7 \" @4 q7 X
研究方向:数值算法理论(光滑有限元法;随机有限元;等几何;无网格法;板壳单元;节点积分);汽车CAE软件开发与集成技术(汽车结构刚度、强度、模态、NVH分析软件;汽车零部件冲压成形分析软件;汽车碰撞分析软件);多物理场计算(结构场、电磁场、热学及声学等工程应用及多场耦合计算);材料成形工艺及机理(电磁成形、3D打印、薄板冲压成形、体积成形等过程的宏观与微观模拟;晶体塑性有限元;多尺度模拟;热处理与组织演变模拟;轻质合金成形机理及本构等)等方面的研究。 [1]
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科研项目[url=]编辑[/url]
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主持项目
$ ^$ Z7 e7 @. ]4 a8 p$ N$ w国家自然科学基金面上项目:“非结构实体-壳交互单元理论及其在电磁成形中的应用研究”% y+ @. i3 b! _% |# P
国家自然科学基金面上项目:“时空间稳定节点积分算法及其在车身设计制造中的应用研究”! q3 `, o' x9 \4 i# e4 q; @
国家自然科学基金青年基金:“连续性二次松弛三角形薄板壳元研究及其在车身设计中的应用”
3 x a+ \: n2 K' I- I湖南省自然科学基金:“动态大变形问题中的节点积分研究”% ~% @/ n& c9 H. a, y* `
车身先进设计制造国家重点实验室自由探索项目:“基于压电声子晶体结构的汽车NVH控制研究”
* p' P& J I- C; n+ D5 N* B* c车身先进设计制造国家重点实验室自由探索项目:“基于非结构网格汽车碰撞软件开发”
; O$ V0 I( \- Y0 C湖南省青年骨干教师资助项目
' C' [+ g2 J0 F博士后基金:“用于材料成形分析的低阶高精度算法理论研究”
/ ]9 Q7 N" x0 i8 b. v湖南省优博资助项目:“低阶高精度单元理论及其在动态大变形问题中的应用研究”9 W z+ e5 O0 ?! J! d) s
青年教师科技创新扶持项目:“新型数值算法研究及其在车身设计中的应用”' s# G3 a/ [2 [% v A/ K. b& O8 @
车车身先进设计制造国家重点实验室人才培育项目:“用于金属塑性成形分析的低阶单元研究”
: O) f, }" ~7 |) l) T, M( t# E: q工业装备结构分析国家重点实验室开放基金:“基于梯度光滑低阶单元理论及其在金属塑性成形分析中的应用研究”
0 |& ]1 }: g" t( X/ l- Y8 e8 H, }: T电动车辆国家工程实验室开放基金:“节点积分拓扑优化理论及其在车身轻量化中的应用研究” [1]# K O3 [! Q1 f" n) f4 \; a
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% \" o/ d. O3 t9 G国家重点研发计划:复杂结构介质大尺度形变高精度高效计算" k. u% Q0 _% U% x9 ~9 D
国家自然科学基金重点项目:面向重大工程需求的CAD/CAE一体化高效计算方法3 c0 H# w* G! Q
国家973计划:现代设计大型应用软件的可信性研究
5 e0 Q! B# f5 `, z+ ^; H国家重点研发计划:轻质材料成形工艺及装配技术研究 [1]; J* F0 @( ~. a3 ?; X r+ s
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学术成果[url=]编辑[/url]
5 s1 P! r% e# b; f最近3年发表的部分论著
7 L0 k% T1 ]! A0 sLiu P W, Wang Z, Xiao Y H, Horstemeyer M F, *Cui X.Y., *Chen L. Insight into the mechanisms of columnar to equiaxed grain transition during metallic additive manufacturing. Additive Manufacturing 2019; 26: 22-29.
. q4 n; p2 N( q2 I2 ELi S, Tian L, *Cui X Y. Phase field crack model with diffuse description for fracture problem and implementation in engineering applications. Advances in Engineering Software 2019;
# ]) L R! \( `5 z9 @ IC.S Ding, X. B Hu, *X.Y Cui, G.Y. Li, Y. Cai, K. K. Tamma. Isogeometric generalized n th order perturbation-based stochastic method for exact geometric modeling of (composite) structures: Static and dynamic analysis with random material parameters. Computer Methods in Applied Mechanics and Engineering 2019; 346:1002-1024.
1 B' c8 ?8 q/ {. p0 Y. DH Yang, *XY Cui, S Li, YH Bie. A stable node-based smoothed finite element method for metal forming analysis. Computational Mechanics 2018; 45:; O" M$ t/ o0 M. P
C.S Ding, R. Deokar, *X.Y Cui, G.Y. Li, Y. Cai, K. K. Tamma. Proper orthogonal decomposition and Monte Carlo based isogeometric stochastic method for material, geometric and force multi-dimensional uncertainties. Computational Mechanics 2018; 45:
3 B2 W$ @0 B* f# E9 pLiu P W, *Cui X.Y., Deng J.S., Li S., Li Z.C, Chen L. Investigation of thermal responses during metallic additive manufacturing using a “Tri-Prism” fnite element method. International Journal of Thermal Sciences 2019; 136: 217-229./ S. ~' T3 b |0 _6 O0 Z$ Z
Pei Y.J., *Cui X Y. A novel triangular prism element based on smoothed finite element method. International Journal of Computational Methods 2018; 15(7):1850058.% s# Q5 V) n; U: V
Liu P W, *Cui X.Y., Wang G., Wang Z., Chen L. An accurate and efficient scheme for linear and nonlinear analyses based on a gradient-weighted technique. International Journal of Non-Linear Mechanics 2018; 105:9-19
0 c8 V! x1 g3 k% [$ ]Li S., *Cui X.Y. An edge-based smoothed finite element method for nonlinear magnetostatic and eddy current analysis. Applied Mathematical Modelling 2018; 62: 287-302.
3 C: i9 x" N, t/ b; TLi S., *Cui X.Y. Li G.Y. Modelling and demonstration of electromagnetically assisted stamping system using an interactive mapping method. International Journal of Mechanical Sciences 2018; 144: 312-323.4 ?2 _; ~ H) S: o9 B
#Liu P W, #Ji Y.Z., Wang Z, Antonysamy A. A, Chen L Q, *Cui X.Y., *Chen L. Investigation on evolution mechanisms of site-specific grain structures during metal additive manufacturing. Journal of Materials Processing Technology 2018; 257: 191-202.
1 a' m+ `4 {1 m" A$ V) A$ Q4 DYan H.H., Bie Y.H., *Cui X Y, Xiong G.P., *Chen L. A computational investigation of thermal effect on lithium dendrite growth. Energy Conversion and Management 2018; 161: 193-204.
/ y2 M1 d0 p# Z1 X! `7 y( AHu X, *Cui X Y, Zhang Q Y, Wang G, Li G Y. Dispersion error analysis of stable node-based finite element method for the helmholtz equation. Communications in Computational Physics. 2018; 23(3):795-821.
8 f; H/ Z( u" ]8 S g5 F. PBie Y.H., *Cui X Y, Li Z.C. A coupling approach of state-based peridynamics with node-based smoothed finite element method. Computer Methods in Applied Mechanics and Engineering 2018; 331:675-700.
2 K, a5 H7 M$ L. _邓家善,裴泳杰,王海波,崔向阳.基于动力学联合仿真的清筛机耙齿磨损分析[J].计算机辅助工程,2018,27(3):15-20., _! H9 k m' f$ w/ k1 c X h
ZC Li, XY Cui, *Y Cai. Analysis of heat transfer problems using a novel low-order FEM based on gradient weighted operation. International Journal of Thermal Sciences 2018; 132:52-64
$ T4 R2 \7 U+ G. XCai Y., Cui X Y, *Li G.Y, Liu W Y. A parallel finite element procedure for contact-impact problems using edge-based smooth triangular element and GPU. Computer Physics Communications 2018; 225: 47-58.
6 H( X4 I; u- W4 WC Ding, X Cui, RR Deokar, G Li, *Y Cai, KK Tamma. An isogeometric independent coefficients (IGA-IC) reduced order method for accurate and efficient transient nonlinear heat conduction analysis. Numerical Heat Transfer, Part A: Applications 2018; 73: 667-684" W5 S9 H1 _8 O
C Ding, X Cui, G.X. Huang, G Li, KK Tamma, *Y Cai. A gradient-based shape optimization scheme via isogeometric exact reanalysis. Engineering Computations 2018; 35: 2696-2721.
3 w( t6 K4 f) G) b6 v; ^D Da, X Cui, K Long, G Huang, *G Li. Design of material microstructures for maximum effective elastic modulus and macrostructures. Engineering Computations 2018; 35 (2): 622-6408 K; P' f ]$ o$ O- n# D
Li S., *Cui X Y, Wang G. Bending and vibration analyses of plate and shell using an element decomposition method. Engineering Computations 2018; 35: 287-314.7 r7 K7 Z( j6 x9 W8 w, h0 y5 S
Yang T.J., *Cui X Y. A random field model based on nodal integration domain for stochastic analysis of heat transfer problems. International Journal of Thermal Sciences 2017; 122: 231-247.' `; w9 q/ |; @& X( v! o0 F
Li S., *Cui X Y , Li G.Y. Multi-physics analysis of electromagnetic forming process using an edge-based smoothed finite element method. International Journal of Mechanical Sciences 2017; 134: 244-252.
, u; n) r# u6 {; }$ s5 R2 A*Cui X Y, Hu X B, Zeng Y. A copula-based perturbation stochastic method for fiber-reinforced composite structures with correlations. Computer Methods in Applied Mechanics and Engineering 2017; 322:351-372.
4 w, c0 f& R) U7 _) ]0 ^1 R6 [Hu X, *Cui X Y, Zhang Q Y, Wang G, Li G Y, The stable node-based smoothed finite element method for analyzing acoustic radiation problems. Engineering Analysis with Boundary Elements 2017; 80: 142-152.
( l0 S1 x4 O7 j$ p. gDa D C, Chen J H, * Cui X Y , *Li G.Y, Design of materials using hybrid cellular automata. Structural and Multidisciplinary Optimization 2017; 56: 131-137.9 w0 g% @# G0 ], `: r
*Cui X Y, Tian L. A central point-based discrete shear gap method for plates and shells analysis using triangular elements. International Journal of Applied Mechanics 2017; 9(4): 1750055(30pages).
8 f6 c( b; W* }# iFeng H., *Cui X Y, Li G.Y. Coupled-field simulation of electromagnetic tube forming process using a stable nodal integration method. International Journal of Mechanical Sciences 2017; 128-129: 332-344.! W, S0 Z3 \6 D/ S/ d' s
Ding C X, *Cui X Y, Huang G X, Li G.Y, Tamma K.K. Exact and efficient isogeometric reanalysis of accurate shape and boundary modifications. Computer Methods in Applied Mechanics and Engineering 2017; 318:619-635.
, A6 G7 s8 R. CFeng H, *Cui X Y, Li G.Y. A stable nodal integration method for static and quasi-static electromagnetic field computation. Journal of Computational Physics 2017; 336: 580-594.6 W+ T5 O% n; X( i+ A
*Cui X Y, Li S, Feng H., Li G.Y. A triangular prism solid and shell interactive mapping element for electromagnetic sheet metal forming process. Journal of Computational Physics 2017; 336: 192-211./ n8 Y, S( [' N$ a8 X/ A5 g
*Cui X Y, Hu X, Wang G, Li G Y, An accurate and efficient scheme for acoustic-structure interaction problems based on unstructured mesh. Computer Methods in Applied Mechanics and Engineering 2017; 317:1122-1145.
) S5 K ^4 k E0 H9 WHu X B, *Cui X Y, Liang Z.M, Li G Y. The performance prediction and optimization of the fiber-reinforced composite structure with uncertain parameters. Composite Structures 2017; 164: 207-218.( X- f( j, P: I2 l2 \; x
Wang G., *Cui X Y, *Li G.Y. Acoustic simulation using a novel approach for reducing dispersion error. International Journal for Numerical Methods in Fluids. 2017; 84:109-134.
, S, ?6 X E0 G& j5 g8 X- _Li S, *Cui X Y, Feng H., Wang G. An electromagnetic forming analysis modelling using nodal integration axisymmetric thin shell. Journal of Materials Processing Technology 2017; 244: 62-72.
3 D! ^# c; n/ H9 R. ^) ?. ?Da D C, Cui X Y, Long K, *Li G.Y. Concurrent topological design of composite structures and the underlying multi-phase materials. Computers & Structures, 2017; 179:1-14.
; Z" _# J; r+ b" M' e9 R/ s9 PWang G., *Cui X Y, *Li G.Y. An element decomposition method for the Helmholtz equation. Communications in Computational Physics. 2016; 20(5):1258-1282. (2区,IF=1.762)
! n, Q) B8 Y6 `' K' e' R4 x8 m( ~Hu X B, *Cui X Y, Feng H, Li G Y. Stochastic analysis using the generalized perturbation stable node-based smoothed finite element method. Engineering Analysis with Boundary Elements 2016; 70: 40-55.7 E7 [$ V( w4 a, i* G/ o
Wang G.,* Cui X Y, Li G Y. A rotation free shell formulation using nodal integration for static and dynamic analyses of structures. International Journal for Numerical Methods in Engineering 2016; 105:532-560
& f3 P" A# {; x9 l- S. l4 T, PFeng S.Z., *Cui X Y, Li A.M. Fast and efficient analysis of transient nonlinear heat conduction problems using combined approximations (CA) method. International Journal of Heat and Mass Transfer 2016; 97: 638-644.
. D3 w, S2 N) k*Cui X Y, Li Z.C, Feng H, Feng S Z. Steady and transient heat transfer analysis using a stable node-based smoothed finite element method. International Journal of Thermal Sciences 2016; 110: 12-25.0 F. ?% h' }. j) n2 f
*Cui X Y, Hu X B, Li G Y, Liu G R. A Modified Smoothed Finite Element Method for Static and Free Vibration Analysis of Solid Mechanics. International Journal of Computational methods 2016, 13(4) 1650043 (31 pages)." \; M8 D0 M% A! I3 e' p% e; f
*Cui X Y, Wang G., Li G Y. A nodal integration axisymmetric thin shell model using linear interpolation. Applied Mathematical Modelling2016; 40: 2720-2742.. x) P+ P) y4 P/ B1 |; L* s; c
崔向阳,胡鑫,王刚,李光耀. 二维声学数值计算的梯度最小二乘加权. 机械工程学报 2016; 52(15): 52-58./ L+ o# A6 j# V% d
Ding C S, Cui X Y, *Li G Y. Accurate analysis and thickness optimization of tailor rolled blanks based on isogeometric analysis. Structural and Multidisciplinary Optimization 2016; 54(4):871-887.: `( B) v! {+ f
Ding C S, Cui X Y, Li C, *Li G Y, Wang G.P. A multi-level refinement adaptive scheme with high efficiency and accuracy. Engineering Computations 2016; 33: 2216 - 2236.3 @0 `9 v8 I/ W( N
Feng H., Cui X Y, *Li G Y. A stable nodal integration method with strain gradient for static and dynamic analysis of solid mechanics. Engineering Analysis with Boundary Elements 2016; 62: 78-92.- O; ~& {9 j( t/ J' X
Feng S.Z., Cui X Y, *Chen F., Li A.M., Liu S.Z., Meng D.Y. An edge/face-based smoothed radial point interpolation method for static analysis of structures. Engineering Analysis with Boundary Elements 2016; 68: 1-10.
1 o" }# g* ^- v: n/ r8 X3 K; q+ L( u7 sFeng S.Z., Cui X Y, *Li A.M., Xie G.Z. A face-based smoothed point interpolation method (FS-PIM) for analysis of nonlinear heat conduction in multi-material bodies. International Journal of Thermal Sciences 2016; 100: 430-437. [1]0 e7 J" q7 N2 z. D# I
参考资料- 1.崔向阳 .湖南大学[引用日期2019-11-09]3 W5 i5 N9 y- P% q0 I9 i- v( q
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发表于 2020-2-21 14:21:00
