Iranian Journal of Manufacturing Engineering

Iranian Journal of Manufacturing Engineering

Modeling and optimization of variables affecting tensile properties of printed PP/Cu composite samples using LDM process

Document Type : Original Article

Authors
Hassanali Mohammadi Jazi 1
Mahdi Vahdati 2
Amir Mahdavi 3
1 MSc Graduate, Faculty of Mechanical Engineering, Shahrood University of Technology, Shahrood, Iran
2 Assistant Professor, Faculty of Mechanical Engineering, Shahrood University of Technology, Shahrood, Iran
3 PhD Student, Faculty of Mechanical Engineering, Shahrood University of Technology, Shahrood, Iran
10.22034/ijme.2024.470528.1989
Abstract
To produce polymer matrix composites, direct printing can be used without the need to make filament. This technology is known as liquid deposition modeling (LDM). In this process, polymer materials mixed with microparticles enter the printer cylinder in the form of granules and after reaching the melting temperature, they are printed on the machine bed. In this research, polymer-based composites made of polypropylene were produced by adding copper microparticles using LDM technology. For this purpose, experimental tests were designed based on a full factorial design. In the following, the composite samples conforming to the geometry of the tensile test sample were printed under certain settings of the input variables including: layer thickness, microparticle size and weight percentage of microparticles, and the yield strength and flexibility of the samples were evaluated based on ANOVA. The results of the statistical analysis showed that the coefficient of variation of the regression models to predict the yield strength and flexibility of the samples are equal to 98.85 % and 98.63%, respectively. Also, dual-objective optimization was performed using the desirability method in order to maximize the response parameters, and the optimal combination of input variables was determined with the desirability value of 96.1%. The optimal values of layer thickness, microparticle size and weight percentage of microparticles were extracted as equal to 180 micron, 45 micron and 10% respectively.
Keywords
Liquid Deposition Modeling
Composite
Polypropylene
Copper
Optimization
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