The continual advancements in 3D-modeling and simulation tools have significantly transformed the landscape of product design and development. This revolution enables the evaluation of object behavior and functionality through simulations before the commencement of physical prototyping. Despite these advancements, the optimization of design parameters remains a formidable challenge for those aiming to produce high-performing products within budgetary and time constraints. Simulation emerges as a potent tool, offering a means to assess and refine designs effectively. This process contributes to improved product performance, decreased manufacturing costs, and a faster time-to-market. This research utilizes the SolidWorks-Simulation to analyze the influence of mechanical properties on the performance of 3D-objects. The evaluation encompasses stress analysis, displacement, and deformation under various loading conditions, considering different materials. Following the ASTM-D628 standard for specimen design-a representation of real-world applications-ensures the findings' relevance and applicability. This study explores two primary parameters under static conditions: the mechanical properties of distinct polymer materials (ABS, PC, PMMA) and varying loading values (1000, 3000, 5000N). The results reveal that ABS absorbs the loading force and deforms with slightly higher values compared to PC and PMMA materials. Moreover, stress values across the proposed materials remain comparable under different loading conditions. As the load increases, ABS and PC materials exhibit a dramatic rise, while PMMA material shows a consistent incremental pattern. In essence, this investigation underscores the profound impact of mechanical properties on the behavior of 3D-objects. This insight enhances the fabrication process and contributes to the development of innovative products that align with customer expectations and industry standards.
Faisal Khaled Aldawood (Tue,) studied this question.