Journal of the Korean Society for Precision Engineering

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Tensile Behavior of 3D Printed Specimens by Small Punch Test: Bum Joon Kim; J. Korean Soc. Precis. Eng. 2025;42(10):879-884.
Published online October 1, 2025; DOI: https://doi.org/10.7736/JKSPE.025.121

Abstract
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The purpose of this study is to evaluate the deformation behavior of 3D printed specimens using the small punch tensile test method. Traditional tensile tests for assessing mechanical properties require a significant amount of material to produce uniaxial tensile specimens. In contrast, the small punch test method only requires 10 x 10 x 0.5 mm (width x length x thickness) thin plate specimens, providing a substantial economic advantage in specimen sampling and production. This method is particularly beneficial when it is impossible to produce specimens of the same size as uniaxial specimens, as it allows tensile testing with just the minimum sample required. In this study, we utilized fused deposition modeling 3D printing and considered various 3D printing parameters, such as layer height and volume fraction, while manufacturing the specimens. We then compared and analyzed the effects of these variables on tensile strength as measured by the small punch tensile test. Furthermore, we focused on investigating the applicability of this method to the deformation behavior of 3D printed specimens. We also examined the impact of laminating conditions, including layer height, printing speed, and laminating direction, on the failure modes observed after the small punch tensile test.

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Effect of Fused Deposition Conditions on the Fracture Behavior of 3D Printed Tensile Specimens: Bum Joon Kim; J. Korean Soc. Precis. Eng. 2020;37(6):421-428.
Published online June 1, 2020; DOI: https://doi.org/10.7736/JKSPE.020.048

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Three-dimensional printing technology has technical limitations limited to the development of prototypes focusing on functional realization. Because of these limitations, there are problems such as mechanical strength and rigidity in entering the commercialization market. However, the industry is working to overcome these obstacles in the future and apply them directly to the field for mass production in the manufacturing process. In particular, research to secure physical properties such as mechanical strength, the major problem of 3D printing products, has been initiated in the automobile industry, aviation, and medical fields. Thus, this study focused on the mechanical strength required for commercialization of 3D printing technology. To achieve this goal, a tensile specimen was fabricated by an FDM (Fused Deposition Modeling) type 3D printer. Tensile specimens were produced of round bar type and the deposition direction, layer height, and printing speed of the layers were considered. Finally, the effects of variables for each printing condition on tensile strength and fracture behavior were compared and analyzed. Also, the fracture surface of the tensile specimen was observed to investigate the effect of the deposition direction on the fracture behavior.

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Enhanced Analysis Model to account for Equivalent Anisotropic Properties of Parts according to 3D Printing Conditions
Chae-Rim Seon, Da-Yeong Jang, Geung Hyeon Lee, Minho Yoon, Jang-woo Han
Journal of the Computational Structural Engineering Institute of Korea.2025; 38(2): 131. CrossRef
Tensile Behavior of 3D Printed Specimens by Small Punch Test
Bum Joon Kim
Journal of the Korean Society for Precision Engineering.2025; 42(10): 879. CrossRef
Experimental Validation of Topology Design Optimization Considering Lamination Direction of Three-dimensional Printing
Hee-Man Park, Gyu-Bin Lee, Jin-san Kim, Chae-Rim Seon, Minho Yoon
Journal of the Computational Structural Engineering Institute of Korea.2022; 35(3): 191. CrossRef