Comparison of Hydrostatic Extrusion between Pressure-Load and Displacement-Load Models

Du, Shengqiang; Zan, Xiang; Li, Ping; Luo, Laima; Zhu, Xiaohua; Wu, Yucheng

doi:10.3390/met7030078

Cited by 3 publications

(2 citation statements)

References 11 publications

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“…Du et al [1] use finite element analysis to simulate hydrostatic extrusion under pressure-and displacement-control. They use these models to examine the relationships between extrusion pressure, extrusion ratio, and die cone angle.…”

Section: Bulk Metal Formingmentioning

confidence: 99%

Advances in Plastic Forming of Metals

Lee

Korkolis

2018

Metals

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Section: Bulk Metal Formingmentioning

confidence: 99%

Advances in Plastic Forming of Metals

Lee

Korkolis

2018

Metals

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“…After reaching the appropriate pressure, the product is extruded through the die. The advantage of the process is the triaxial stress state acting on the workpiece in the working chamber, inhibiting the formation of cracks and their propagation in the deformed material [ 2 , 3 ]. This allows the deformation of hard-to-deform materials due to external stress and extrusion ratios that are higher than other extrusion processes at ambient temperature [ 1 ].…”

Section: Introductionmentioning

confidence: 99%

Static and Dynamic Properties of Al-Mg Alloys Subjected to Hydrostatic Extrusion

et al. 2022

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The aim of this study is to determine the influence of the amount of magnesium in Al-Mg alloys and strain rate on the grain refinement and mechanical properties of the material as determined in a dynamic tensile test. Hydrostatic extrusion was used to process the material. This method is not commonly used to impose severe plastic deformation of Al-Mg alloys. The article presents the results of static and dynamic strength tests on aluminium alloys subjected to plastic deformation in the hydrostatic extrusion process. Technically pure aluminium Al99.5 and three aluminium alloys with different magnesium content, Al-1Mg, Al-3Mg and Al-7.5Mg, were used in the tests. The samples were subjected to static tests using the uniaxial tensile test machine and dynamic tests using a rotary hammer. Compared to pure aluminium, increasing the magnesium content in Al-based alloys strengthened them in hydrostatic extrusion (logarithmic strain ε = 0.86) and caused an increase in the static ultimate tensile stress Rm, relative strain εr and the value of the yield stress. For strengthened aluminium alloys, an increase in the strain rate from 750 to 1750 s−1 caused an increase in the dynamic ultimate tensile stress from 1.2 to 1.9 times in relation to the static ultimate tensile stress. The increase in magnesium content results in the formation of a larger strengthening phase, influences a different state of stress during dynamic loading and leads to a change in the orientation of the fracture surface. It was also found that an increase in magnesium content is associated with an increased number of voids, which is also directly proportional to the strain rate in the dynamic rotary hammer test.

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Numerical Simulation and Experimental Research of the Hydrostatic Extrusion Process of Pure Tungsten

Hong

Zan

et al. 2018

Springer Proceedings in Energy

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Comparison of Hydrostatic Extrusion between Pressure-Load and Displacement-Load Models

Cited by 3 publications

References 11 publications

Advances in Plastic Forming of Metals

Advances in Plastic Forming of Metals

Static and Dynamic Properties of Al-Mg Alloys Subjected to Hydrostatic Extrusion

Numerical Simulation and Experimental Research of the Hydrostatic Extrusion Process of Pure Tungsten

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