Optimized Packing of 3D Objects Bounded by Spherical and Conical Surfaces

Kibernetika ta kompiuterni tekhnologiyi Pub Date : 2023-09-29 DOI:10.34229/2707-451x.23.3.1

Andrii Chuhai, Tetyana Romanova, Georgiy Yaskov, Mykola Gil, Sergiy Shekhotsov

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Abstract

Introduction. Optimizing the packing of arbitrary geometric objects in additive manufacturing opens up new possibilities for increasing the efficiency of additive manufacturing of parts of a complex configuration due to the saving of energy, material and time resources. Additive manufacturing, a cornerstone in fields such as space engineering, medicine, mechanical engineering, and energy, has its efficiency hinging on the optimization of the 3D printing process. Given its widespread application, refining this process is of utmost importance. The purpose of the paper. The paper aims to develop an approach for packing assembled parts of complex geometry in the working area of a 3D printer, while adhering to the standards of 3D printing. Results. For the analytical description of the complex shaped industrial products, a, so called, “composed spherical cone” is used. This generates a family of such objects as spheres, cylinders, spherical cylinders, cones, truncated cones and spherical discs. Using the normalized quasi-phi-function of composed spherical cones, a mathematical model of the problem is presented in the form of a nonlinear programming problem. A solution strategy is developed, encompassing three primary stages: generation of feasible starting points, search of local minima and search of a better local minimum. Numerical examples of packing various industrial products in a 3D printer chamber is provided. 3D-parts are approximated by composed spherical cones with different metric parameters. Conclusions. The conducted numerical simulation confirms the effectiveness of the proposed optimization approach. This study emphasizes the importance of further research and innovation in the field of 3D printing and its optimization, and also demonstrates the potential of using mathematical models to solve practical problems in a production environment. Keywords: packing, assembled spherical cone, mathematical modeling, optimization, additive manufacturing.

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以球面和圆锥曲面为界的三维物体的优化填充

介绍。在增材制造中优化任意几何物体的包装，为提高复杂结构零件的增材制造效率开辟了新的可能性，因为它节省了能源、材料和时间资源。增材制造是空间工程、医学、机械工程和能源等领域的基石，其效率取决于3D打印过程的优化。鉴于其广泛的应用，改进这一过程是至关重要的。论文的目的。本文旨在开发一种在3D打印机工作区域内包装复杂几何形状组装件的方法，同时坚持3D打印的标准。结果。对于形状复杂的工业产品的分析描述，使用了所谓的“组合球锥”。这将生成一系列诸如球体、圆柱体、球圆柱体、锥、截锥和球盘之类的物体。利用组合球锥的归一化拟函数，以非线性规划问题的形式建立了该问题的数学模型。提出了一种求解策略，该策略包括三个主要阶段:可行起始点的生成、局部极小值的搜索和更好的局部极小值的搜索。提供了在3D打印机腔内包装各种工业产品的数值示例。三维零件是由具有不同度量参数的组合球锥来逼近的。结论。数值模拟验证了所提优化方法的有效性。这项研究强调了在3D打印及其优化领域进一步研究和创新的重要性，也展示了利用数学模型解决生产环境中实际问题的潜力。关键词:填料，装配球锥，数学建模，优化，增材制造。

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Kibernetika ta kompiuterni tekhnologiyi

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审稿时长

6 weeks