Effect of the Number of Shells on Selected Mechanical Properties of Parts Manufactured by FDM/FFF Technology

Szot, Wiktor; Rudnik, Mateusz

doi:10.2478/adms-2024-0006

Abstract

The technological parameters of 3D printing have an influence on the mechanical properties of the manufactured components. The purpose of the article was to study the comparative influence of the technological parameter of the number of shells variable in two stages (2 and 10) on selected mechanical properties. The maximum tensile stress for the number of shells 10 was 39.80 MPa, which is higher compared to the number of shells 2: 30.98 MPa. In the case of the maximum bending stress for the number of shells 10, an average value of 61.02 MPa was obtained, which is higher compared to the number of shells of 2: 37.46 MPa. Furthermore strong fit of the Kelvin-Voight model was obtained, as confirmed by the values of the Cℎi²: 0.0001 and R²: 0.997 coefficients.

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Effect of the Number of Shells on Selected Mechanical Properties of Parts Manufactured by FDM/FFF Technology

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