Mass Optimization of Crane Box Girder Considering Both Ribs and Diaphragms using APDL

IF 1.1 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY International Journal of Steel Structures Pub Date : 2024-05-10 DOI:10.1007/s13296-024-00846-3
Yangzhi Ren, Xuechun Liu, Bin Wang
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Abstract

Mass optimization of crane box girder considering both ribs and diaphragms is a crucial aspect of crane structural design in mechanical engineering. However, two common challenges often obscure this process: the sizing of stiffeners such as diaphragms and ribs, and the selection of constraints on state variables related to stresses and deformations for various load cases. In response, this paper focuses on optimizing the dimensions, number, and placement of stiffeners, including ribs and diaphragms, in a two-girder overhead crane structure. The paper begins by establishing criteria for the initial height of the box girder through a comparative analysis of structural strength and stiffness. Subsequently, dimensional relationships between stiffeners and the girder section are built in accordance with the principles of local plate stability. Following this, the ANSYS Parametric Design Language (APDL) program is coded and executed to optimize the crane mass using three methods: sub-problem approximation, sweep, and first-order methods via Module Design OPT for four chosen sets of state variables. A comparative analysis of the optimum crane mass, based on the rounded-up design variables, reveals that constraints on stresses and deformations from both vertical and transversal impact cases, as well as the vertical frequency from dynamic vibration cases, yield the best results. Furthermore, the proposed APDL method is compared and validated against Grey Wolf Optimizer, Whale Optimization Algorithm, Particle Swarm Optimization, and Genetic Algorithm. Finally, a parametric study is conducted using curves and tables to explore the influence of structural stiffness and material property on the optimized dimensions of the girder and stiffeners, as well as the overall mass and mechanical performance.

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使用 APDL 对同时考虑肋骨和横隔梁的起重机箱梁进行质量优化
在机械工程中,考虑肋骨和横隔梁的起重机箱梁质量优化是起重机结构设计的一个重要方面。然而,在这一过程中往往会遇到两个共同的难题:一是如何确定横隔梁和肋条等加劲件的尺寸,二是如何选择各种载荷情况下与应力和变形相关的状态变量约束。为此,本文重点讨论了如何优化双梁桥式起重机结构中加劲件(包括肋条和隔膜)的尺寸、数量和位置。本文首先通过对结构强度和刚度的比较分析,确定了箱梁初始高度的标准。随后,根据局部板稳定性原则,建立加劲件和梁截面之间的尺寸关系。随后,对 ANSYS 参数化设计语言(APDL)程序进行编码和执行,使用三种方法对起重机质量进行优化:子问题逼近法、扫掠法,以及通过模块设计 OPT 对四组选定的状态变量使用一阶方法。根据四舍五入的设计变量对最佳起重机质量进行的比较分析表明,垂直和横向冲击情况下的应力和变形约束,以及动态振动情况下的垂直频率约束,都能产生最佳结果。此外,提出的 APDL 方法还与灰狼优化算法、鲸鱼优化算法、粒子群优化算法和遗传算法进行了比较和验证。最后,使用曲线和表格进行了参数研究,以探讨结构刚度和材料特性对大梁和加劲件优化尺寸以及整体质量和机械性能的影响。
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来源期刊
International Journal of Steel Structures
International Journal of Steel Structures 工程技术-工程:土木
CiteScore
2.70
自引率
13.30%
发文量
122
审稿时长
12 months
期刊介绍: The International Journal of Steel Structures provides an international forum for a broad classification of technical papers in steel structural research and its applications. The journal aims to reach not only researchers, but also practicing engineers. Coverage encompasses such topics as stability, fatigue, non-linear behavior, dynamics, reliability, fire, design codes, computer-aided analysis and design, optimization, expert systems, connections, fabrications, maintenance, bridges, off-shore structures, jetties, stadiums, transmission towers, marine vessels, storage tanks, pressure vessels, aerospace, and pipelines and more.
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