Accurate friction and heat transfer laws for enhanced simulation models of precision forging processes

Doege, E.; Alasti, M.; Schmidt-Jürgensen, R.

doi:10.1016/j.jmatprotec.2004.01.025

Cited by 10 publications

(5 citation statements)

References 4 publications

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“…In the same study, it has been shown that the required force for forging decreased with increasing the temperature. (Ou and Balendra, 1998) and (Doege et al, 2004) showed that at the same temperature and various friction coefficients, punch force increased by increasing the friction coefficient. Regression analysis of pressing velocity, temperature and friction coefficient on punch force showed that there were significant effects on dependent variable (Table 3).…”

Section: Resultsmentioning

confidence: 98%

Analysis of Hip Prosthesis Production With Forging Using the Finite Element Method

2015

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Hip prostheses used to fulfill injured or fractured limbs are made by machining, casting and plastic forming. Machining is the most commonly used one. However, there are many disadvantages such as high product cost in machining. Plastic forming methods provide more effective and durable implant production than machining. In this study, hip prosthesis with a complex geometry produced by forging were analyzed using the Finite Element Method (FEM). For this purpose, three-dimensional complex geometry was designed and then, FEM analyses were performed using MSC SIMUFACT 10 software. Factors affecting the production were defined as: temperature, friction coefficient and the pressing velocity. Stress distributions, temperature changes, die wears and punch forces applied to the die were examined. As a result of the study, the most suitable parameters were obtained as 500°C, 0.05 coefficient of friction and 2mm/s die velocity. Also, the obtained FEM results were examined by regression analyses.

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Section: Resultsmentioning

confidence: 98%

Analysis of Hip Prosthesis Production With Forging Using the Finite Element Method

2015

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“…In the model, the sliding velocity, equivalent stress, and yield stress were considered, as shown in Fig. 17(b) [76]. An empirically-based friction model describes friction as a function of the sliding distance and the most relevant friction influencing parameters [77].…”

Section: Friction Models and Gallingmentioning

confidence: 99%

Galling phenomena in metal forming

Dohda

Yamamoto

et al. 2020

Friction

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Galling phenomena in metal forming not only affect the quality of the engineered surfaces but also the success or failure of the manufacturing operation itself. This paper reviews the different galling conditions in sheet and bulk metal forming processes along with their evolution and the effects of temperature on galling. A group of anti-galling methods employed to prevent galling defects are also presented in detail. The techniques for quantitatively measuring galling are introduced, and the related prediction models, including friction, wear, and galling growth models, are presented to better understand the underlying phenomena. Galling phenomena in other processes similar to those occurring in metal forming are also examined to suggest different ways of further studying galling in metal forming. Finally, future research directions for the study of galling in metal forming are suggested.

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“…where [K] is the 6 × 6 press stiffness matrix, {γ} is the 6 × 1 press deflection vector, {γ eq o } is the 6 × 1 equivalent vector of the press guideway clearance and {P} is the 6 × 1 forging force vector, respectively. Therefore using equation (10), it is possible to accommodate the press elastic deflections in a forging simulation and to predict the dimensional errors of a forged part due to press elasticity. As shown in figure 5(b), 2D and 3D beam and coupling elements may be used to enable a proper load distribution and kinematic constraints between the press and the forging die in forging simulation to include the press elasticity effect.…”

Section: Representation Of Press Elasticitymentioning

confidence: 99%

“…Due to the forging dies being mounted rigidly on the press ram and table, the die surface displacement due to press elasticity at any given position can be calculated by the translation and rotation of the press ram. Based on equation (10), a matrix transformation of the press deflections may be further derived to predict the die surface deviation where {∆r i } is the 3 × 1 vector of the die surface deviation and [C i ] is the 3 × 6 coordinate transformation matrix at any given node i on the forging die surface, which represents the spatial relationships between the forging dies and the press ram. Equation ( 11) also suggests that the forging errors due to press elasticity and guideway clearance may be established by the spatial relationship of the forging dies mounted on the press ram and table, the press stiffness characteristics, the forging force and equivalent clearance values [9].…”

Section: Representation Of Press Elasticitymentioning

confidence: 99%

“…Recent development in process simulation shows that different stages of the whole forging process including pre-forging, forging and post forging may be simulated in coupling with the thermal behaviour and tool/press elasticity [7][8][9]. Parallelly to numerical simulation of forging processes, progress has been made in developing new experimental methods and constitutive models for the interfacial behaviour such as the friction and heat transfer as well as the material rheological behaviour under hot working conditions [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Reduction in post forging errors for aerofoil forging using finite element simulation and optimization

Ou¹,

Lan²,

Armstrong³

et al. 2006

Modelling Simul. Mater. Sci. Eng.

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This paper reports on recent work in the development of a finite element (FE) based forging optimization methodology. It utilizes the commercial FE package ABAQUS and the optimization code VisualDOC. Taking into account the effect of die and press elastic deflections and thermal distortion in cooling, a direct compensation approach and optimized weighting factor method are used to achieve the optimized die shape for improved dimensional accuracy of forged aerofoil blades. The significant predicted reduction in aerofoil shape errors using a single 2D section from a forged nickel-based blade demonstrates the efficiency and potential for applying this approach to more complex, realistic and industrially relevant 3D forging problems.

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Accurate friction and heat transfer laws for enhanced simulation models of precision forging processes

Cited by 10 publications

References 4 publications

Analysis of Hip Prosthesis Production With Forging Using the Finite Element Method

Analysis of Hip Prosthesis Production With Forging Using the Finite Element Method

Galling phenomena in metal forming

Reduction in post forging errors for aerofoil forging using finite element simulation and optimization

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