Simulation of the hot isostatic pressing process

Q3 Materials Science

PNRPU Mechanics Bulletin Pub Date : 2021-12-15 DOI:10.15593/perm.mech/2021.3.18

A. A. Khlybov, E. S. Belyaev, A. D. Ryabtsev, D. Ryabov, S. Belyaeva, Yu. A. Getmanovsky, P. M. Yavtushenko

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Abstract

This work, models the compaction of a dispersed body under the conditions of a hot isostatic pressing (HIP) cycle using the example of the manufacture of compacts from VZh159ID powder and Inconel alloy 718. For the research, VZh159ID powder of fraction -70 + 25 μm, bulk density of 3.77 g/cm3 (4.83 g/cm3 after tapping), fluidity of 2.3 g/s, specific surface area of 446 cm2/g, and average particle size was used according to Fisher 16 microns, as well as Inconel alloy 718 powder of fraction -315 + 25 microns, bulk density 3.84 ... 4.58 g/cm3 (4.52 ... 5.24 gcm3 after tapping), fluidity 1.58 ... 1.90 g/s, specific surface 330 ... 376 cm2/g and average particle size according to Fischer 19.0 ... 19.5 microns. Before the HIP cycle, the powder backfills underwent thermal degassing in vacuum, since powders with such a high specific surface are subject to rapid gas sorption. Gases on the surface of the powder body as a result of the HIP cycle can form non-metallic inclusions that reduce the properties of the compact. In the microstructure of compacts after HIP, there is no network of residual boundaries from granules (PPBs-Prior Particle Boundaries), which indicates an effective technology of vacuum degassing of the powder. Simulation of the compaction process was carried out according to the modernized equation of E. Ryshkevich, constants b were selected for the materials considered. The results of the experiments of interrupting the HIP cycle and data on the strength of the samples at high temperatures obtained by selective laser sintering were used as the initial data for modeling. The proposed modeling method is quite simple (does not require experiments on an interrupted HIP cycle) due to the shown possibility of experimentally determining the strength characteristics of alloys at elevated temperatures on samples obtained by selective laser sintering. The analysis of the obtained microstructures (estimation of porosity) of the samples after HIP, having different density values, shows a good agreement of the proposed model with the real process of compaction in the gasostatic extruder.

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热等静压过程的模拟

这项工作使用由VZh159ID粉末和铬镍铁合金718制造压块的例子，对在热等静压（HIP）循环的条件下分散体的压实进行了建模。在研究中，使用了分数为-70+25μm的VZh159ID粉末，堆积密度为3.77 g/cm3（攻丝后为4.83 g/cm3），流动性为2.3 g/s，比表面积为446 cm2/g，平均粒度为Fisher 16微米，以及分数为-315+25微米的铬镍铁合金718粉末，堆积密度为3.84…4.58 g/cm3（攻丝前为4.52…5.24 gcm3），流动性1.58…1.90 g/s，比表面积330。。。376cm2/g，根据Fischer的平均粒度为19.0…19.5微米。在HIP循环之前，粉末回填料在真空中进行热脱气，因为具有如此高比表面的粉末会快速吸收气体。HIP循环导致粉末体表面的气体会形成非金属夹杂物，从而降低压块的性能。在HIP后的压块微观结构中，没有来自颗粒的残余边界网络（PPBs-Prior Particle boundaries），这表明粉末的真空脱气是一种有效的技术。根据E.Ryshkevich的现代化方程对压实过程进行了模拟，所考虑的材料选择了常数b。中断HIP循环的实验结果和通过选择性激光烧结获得的样品在高温下的强度数据被用作建模的初始数据。所提出的建模方法非常简单（不需要在中断的HIP循环上进行实验），因为所显示的在通过选择性激光烧结获得的样品上实验确定合金在高温下的强度特性的可能性。对HIP后获得的具有不同密度值的样品的微观结构（孔隙率的估计）的分析表明，所提出的模型与气体稳定挤出机中的实际压实过程非常一致。

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来源期刊

PNRPU Mechanics Bulletin Materials Science-Materials Science (miscellaneous)

CiteScore

1.10

自引率

0.00%

发文量