# Analysis of Thermal Stresses in Solidification of Spherical SLM   Components

**Authors:** Amir Mahyar Khorasani, Ian Gibson, Moshe Goldberg, Mohammad Masoud, Movahedi, Guy Littlefair

arXiv: 1706.08212 · 2017-06-27

## TL;DR

This paper analyzes thermal stresses during the selective laser melting process of spherical components, focusing on their effects on geometry and process stability, with implications for manufacturing medical implants like acetabular shells.

## Contribution

It introduces a detailed analysis of build-up lines caused by thermal stresses in SLM, incorporating Gibbs free energy and interfacial energy considerations, to improve manufacturing accuracy of prosthetic components.

## Key findings

- Geometrical deviations of 1.59% and 0.27% in prototype diameters.
- Thermal stress flow influences build-up lines and process stopping.
- Insights into Gibbs free energy effects on SLM processes.

## Abstract

The majority of these machines fabricate from raw material in powder form using a directed energy beam to create a local melt zone. Total hip replacement is recommended for people who have medical issues related to excessive wear of the acetabular, osteoarthritis, accident or age. Researches have shown that large numbers of hip arthroplasties (where the articular surface of a musculoskeletal joint is replaced), hip remodelling, or realignment are carried out annually and will increase in the next few decades. Manufacturing of acetabular shells by using AM is a promising and emerging method that has a great potential to improve public health. Lost wax casting or investment casting is currently used to produce acetabular shells followed by lengthy and complex secondary processes such as machining and polishing. Living organs and medical models have intricate 3D shapes that are challenging to identity in X-ray CT images. These images are used for preparing treatment plans to improve the quality of the surgeries regarding waiting and surgery time per procedure and care regime. For instance, a limited number of hip replacement procedures can be carried out on each acetabulum due to a decrease of bone thickness. Rapid prototyping is a suitable treatment planning tool in complex cases to enhance the quality of surgical procedure and provide long-term stability that can be used to customize the shape and size of the acetabular shell. In this paper, to analyse the manufacturing of a prosthetic acetabular shell, built-up lines resulting from a thermal stress flow and process stopping during the selective laser melting (SLM) AM process, with regarding Gibbs free energy, interfacial energy, and equilibrium temperature will be discussed. Geometrical measurements showed 1.59% and 0.27% differences between the designed and manufactured prototype for inside and outside diameter respectively.

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Source: https://tomesphere.com/paper/1706.08212