A generally suited method to get initial guess solutions for one-step and multi-step simulations of tube and profile forming based on parameterization. (English) Zbl 1358.74071
Summary: In one-step and multi-step simulations, how to get initial guess solutions effectively is a key point, which has gained great attention during the past decades. However, most of the achievements have been targeted at sheet metal forming, rarely at tube or profile forming, which hinders the applications of one- and multi-step approach to tube and profile forming. A new method, based on the parameterization in computer graphics, is presented in this paper, in which a sort of parameterized computation defined in the cylindrical coordinate system is utilized to produce initial guess solution for initial configuration, and a simple but effective geometric algorithm on the basis of the parameterization is proposed for intermediate configuration. Different from the original plane parameterization, the parameterized computation in this method is to map mesh onto initial straight tube or profile surface instead of plane. The method is highly efficient since only one set of large sparse linear equations needs to be solved in the parameterized computation and the geometric algorithm for intermediate configuration is also fast in mesh-mapping. In order to verify the validity and efficiency of the presented method, several numerical examples are provided and the obtained initial guess meshes are satisfactory.
MSC:
| 74S30 | Other numerical methods in solid mechanics (MSC2010) |
Keywords:
initial guess solutions; one-step approach; multi-step approach; tube and profile forming; plane parameterizationReferences:
| [1] | Chung, A deformation theory of plasticity based on minimum work paths, International Journal of Plasticity 9 pp 907– (1993) · Zbl 0793.73034 · doi:10.1016/0749-6419(93)90057-W |
| [2] | Chung, Mechanics of ideal forming, Journal of Applied Mechanics 61 pp 176– (1994) · Zbl 0816.73020 · doi:10.1115/1.2901394 |
| [3] | Chung, Ideal flow in plasticity, Applied Mechanics Reviews 60 pp 316– (2007) · doi:10.1115/1.2804331 |
| [4] | Guo, Initial solution estimation to speed up inverse approach in stamping modeling, Engineering Computations 20 (7) pp 810– (2003) · Zbl 1063.74512 · doi:10.1108/02644400310501992 |
| [5] | Wang, Research on initial solution estimation in inverse approach for sheet metal forming, Journal of Plasticity Engineering 12 (4) pp 19– (2005) |
| [6] | Lu, Application of section curve expanding method in one step forming, Journal of Jilin University (Engineering and Technology Edition) 34 (1) pp 52– (2004) |
| [7] | Lee, Blank design and strain estimates for sheet metal forming processes by a finite element inverse approach with initial guess of linear deformation, Journal of Materials Processing Technology 82 pp 145– (1998) · doi:10.1016/S0924-0136(98)00034-X |
| [8] | Tang, Energy based algorithms to solve initial solution in one-step finite element method of sheet metal stamping, Computer Methods in Applied Mechanics and Engineering 196 pp 2187– (2007) · Zbl 1173.74445 · doi:10.1016/j.cma.2006.11.015 |
| [9] | Floater, Parameterization and smooth approximation of surface triangulations, Computer Aided Geometric Design 14 pp 231– (1997) · Zbl 0906.68162 · doi:10.1016/S0167-8396(96)00031-3 |
| [10] | Pinkall, Computing discrete minimal surfaces, Experimental Mathematics 2 1 pp 15– (1993) · Zbl 0799.53008 · doi:10.1080/10586458.1993.10504266 |
| [11] | Eck M Derose T Duchamp T Hoppey H Lounsberyz M Stuetzle W Multiresolution analysis of arbitrary meshes 173 182 |
| [12] | Desbrun, Intrinsic parameterization of surface meshes, Computer Graphics Forum 21 (3) pp 209– (2002) · doi:10.1111/1467-8659.00580 |
| [13] | Lee, Mesh parameterization with a virtual boundary, Computers and Graphics 26 pp 677– (2002) · doi:10.1016/S0097-8493(02)00123-1 |
| [14] | Sederberg TW Gao P Wang G Mu H 2-D shape blending: an intrinsic solution to the vertex path problem 15 18 |
| [15] | Kim, Construction of sliding constraint surfaces and initial guess shapes for intermediate steps in multi-step finite element inverse analysis, Journal of Materials Processing Technology 130-131 pp 482– (2002) · doi:10.1016/S0924-0136(02)00791-4 |
| [16] | Huang, A new approach to solve key issues in multi-step inverse finite-element method in sheet metal stamping, International Journal of Mechanical Sciences 48 pp 591– (2006) · Zbl 1192.74358 · doi:10.1016/j.ijmecsci.2006.01.007 |
| [17] | Wu, A different fast simulation of multi-step sheet metal forming based on double spreading plane mapping method, Journal of Northwestern Polytechnical University 26 (5) pp 645– (2008) |
| [18] | Dong ZT Study on finite element simulation and test of hydro-bulging axle housings 2007 |
| [19] | Lei, Rigid-plastic finite element analysis of hydroforming process and its applications, Journal of Materials Processing Technology 139 pp 187– (2003) · doi:10.1016/S0924-0136(03)00218-8 |
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