Feasible pressure and axial feed path determination for fuel filler tube hydroforming by genetic algorithm

Intarakumthornchai, Thanasan; Aue‐u‐lan, Yingyot; Kesvarakul, Ramil; Jirathearanat, Suwat

doi:10.1177/0954405414559076

Cited by 13 publications

(7 citation statements)

References 17 publications

(19 reference statements)

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“…Di Lorenzo et al [18,19] proposed a gradient decomposition method, which aimed to reduce the number of evaluations of FE simulation, to optimize the internal pressure and counter punch action in Y-shape THF process. Intarakumthornchai et al [20] applied genetic algorithm (GA) to obtain and determine the loading path for fuel filler THF process. Mirzaali et al [21,22] used simulated annealing algorithm to find the optimal loading parameters in THF process with and without axial force loading conditions.…”

Section: Introductionmentioning

confidence: 99%

The multi-objective optimization of the loading paths for T-shape tube hydroforming using adaptive support vector regression

Huang

Song

Liu

2016

Int J Adv Manuf Technol

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The objective of this study is to introduce adaptive support vector regression, whose accuracy and efficiency are illustrated through a numerical example, to determine the Pareto optimal solution set for T-shape tube hydroforming process. A validated finite element model developed by the explicit finite element code LS-DYNA is used to conduct virtual T-shape tube hydroforming experiments. Multiobjective optimization problem considering contact area between the tube and counter punch, maximum thinning ratio, and protrusion height is formulated. Then, the Latin hypercube design is employed to construct the initial support vector regression model, and some extra sampling points are added to reconstruct the support vector regression model to obtain the Pareto optimal solution set during each iteration. Finally, the ideal point is used to obtain a compromise solution from the Pareto optimal solution set for the engineers.

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Section: Introductionmentioning

confidence: 99%

The multi-objective optimization of the loading paths for T-shape tube hydroforming using adaptive support vector regression

Huang

Song

Liu

2016

Int J Adv Manuf Technol

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“…In general, the fluid pressure is assumed to be hydrostatic and universal throughout the application and follow the pressure curve. These kinds of simulations enable the hydroforming process by allowing for the optimization of a function (often based upon minimal material thinning and wrinkling) [45] instead of a more traditional empirically derived equation method, e.g. a calculation of a pressure curve that suppresses buckling using the energy method [55].…”

Section: Analytical Methods and Numerical Simulationsmentioning

confidence: 99%

“…A load path is a statement of how much fluid pressure (and axial force in the case of tube hydroforming) is applied at a given time through a forming process. They are created by Biterative finite element analyses with adjustments based on forming experience… due to the highly nonlinear nature of the tube hydroforming process [ 45]. There are numerous studies in the relevant literature which explore how process windows and load paths are created and how they can be expanded or optimized but there are many challenges in doing so.…”

Section: Process Windows and Loading Pathsmentioning

confidence: 99%

“…Alternately, instead of designing a specific function ahead of time, Xiang et al looked at 9 different theoretical load paths and made a determination about which was best by looking at their effects on the results of an FEA analysis [53]. Intarakumthornichai et al used a genetic algorithm based upon a two part quality criteria (minimization of thinning and elimination of wrinkles) [45]. Ge et al used a similar multiobjective optimization function with differential evolution in a tube hydroforming operation to optimize a loading path [54].…”

Section: Process Windows and Loading Pathsmentioning

confidence: 99%

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A state of the art review of hydroforming technology

et al. 2019

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Hydroforming is a relatively new metal forming process with many advantages over traditional cold forming processes including the ability to create more complicated components with fewer operations. For certain geometries, hydroforming technology permits the creation of parts that are lighter weight, have stiffer properties, are cheaper to produce and can be manufactured from fewer blanks which produces less material waste. This paper provides a detailed survey of the hydroforming literature of both established and emerging processes in a single taxonomy. Recently reported innovations in hydroforming processes (which are incorporated in the taxonomy) are also detailed and classified in terms of “technology readiness level”. The paper concludes with a discussion on the future of hydroforming including the current state of the art techniques, the research directions, and the process advantages to make predictions about emerging hydroforming technologies.

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“…Huang et al [26] used the Kriging method to build proxy model for loading path design of T-tube hydroforming, and the robustness and reliability of this method were verified. Intarakumthornchai et al [27] integrated genetic algorithms into finite element analysis for determination of feasible loading paths.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Process Parameters during Hydroforming of Tank Bottom using NSGA-III Algorithm

Zhang

Sun

2021

Preprint

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The hydroforming technology can realize overall forming of large storage tank’s bottom, but the quality is affected by many technological parameters. In view of wrinkling and cracking defects of integral storage tank’s bottom in hydroforming, a multi-objective optimization model is established for process parameters include pre-expansion pressure, hydraulic pressure, blank holder force and fillet radius of blank holder. Based on finite element simulation, the surrogate model between process parameters and quality criteria is established using Kriging technique. NSGA-III is used to determine optimal process parameters when storage tank’s bottom reaches targets include minimum wall thickness variations, minimum fracture trend, minimum flange wrinkle and minimum wrinkle trend. Compared with Particle swarm optimization (PSO) algorithm, NSGA-III algorithm is more suitable to solve this optimization problem. The validity of this method and accuracy of the results are verified by simulation experiments.

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Feasible pressure and axial feed path determination for fuel filler tube hydroforming by genetic algorithm

Cited by 13 publications

References 17 publications

The multi-objective optimization of the loading paths for T-shape tube hydroforming using adaptive support vector regression

The multi-objective optimization of the loading paths for T-shape tube hydroforming using adaptive support vector regression

A state of the art review of hydroforming technology

Optimization of Process Parameters during Hydroforming of Tank Bottom using NSGA-III Algorithm

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