纺织学报 ›› 2025, Vol. 46 ›› Issue (05): 252-261.doi: 10.13475/j.fzxb.20240600301

• 机械与设备 • 上一篇    下一篇

基于多工况的铲式落布车车身设计与优化

宋栓军(), 尚长伟, 张家豪, 周进良   

  1. 西安工程大学 机电工程学院, 陕西 西安 710048
  • 收稿日期:2024-06-03 修回日期:2024-12-31 出版日期:2025-05-15 发布日期:2025-06-18
  • 作者简介:宋栓军(1974—),男,教授,博士。主要研究方向为机器人技术、生产系统优化等。E-mail:songshuanjun@126.com
  • 基金资助:
    国家自然科学基金项目(72001166);陕西省重点研发计划项目(2023-YBGY-349)

Body design and optimization of shovel type fabric unloading vehicle based on multi-working conditions

SONG Shuanjun(), SHANG Changwei, ZHANG Jiahao, ZHOU Jinliang   

  1. College of Mechanical and Electrical Engineering, Xi'an Polytechnic University, Xi'an, Shaanxi 710048, China
  • Received:2024-06-03 Revised:2024-12-31 Published:2025-05-15 Online:2025-06-18

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摘要:

为解决当前落布车车身重、无法适应不同幅宽布辊、工作过程中稳定性差等问题,结合落布过程中的7种工况,基于拓扑优化的方法设计了一款轻量化、高稳定性的铲式落布车。首先对车身基本结构进行了力学分析,得出载荷分配与车轮位置的关系。在此基础上,通过7种工况下的静态结构分析得到影响车身结构的权重比,将各工况的权重比、车身振动特征和模态参数作为车身拓扑优化问题的依据条件,随后对其形状尺寸进行优化,以此获得最优车身结构设计方案。通过仿真实验,对比分析了优化前后落布车的车身刚度、模态等性能。结果表明,考虑多工况的优化方案其车身减重32.5%,各工况下稳定性明显提升。

关键词: 车身结构, 轻量化, 力学分析, 多工况, 拓扑优化, 仿真分析, 落布车

Abstract:

Objective In the textile workshop, the handling of full rolls of fabric sticks is a key and difficult problem. There are design problems in the existing fabric unloading vehicle, which cause it to consume a lot of energy in the process of handling to overcome its own weight, and the poor stability of the vehicle body also affects the transportation efficiency. Therefore, it is of great significance to optimize the vehicle body structure of the fabric unloading vehicle to achieve the design goals of equal strength, light weight and high stability.
Method Aiming at the problems such as high body weight and poor stability, a system-level optimization method was introduced to improve the anti-torsional performance and the uniformity of modal natural frequency distribution and eliminate the potential stress concentration by optimizing the overall design, material and layout of the vehicle body. At the same time, considering several working conditions, the topological optimization method is utilized to adjust the material distribution, which can meet the requirements of structural strength and stiffness to the maximum extent and reduce the weight of the vehicle body. The comprehensive application of these optimization methods provides a new idea for the precise design and efficient optimization of the vehicle body structure of the fabric unloading vehicle.
Results This paper introduces a comprehensive optimization methodology addressing vehicle body weight, stability, and the design of a specialized fabric unloading vehicle. By meticulously optimizing the vehicle body's structure, materials, and layout, improvements in anti-torsional resilience and modal frequency distribution uniformity are achieved, effectively eliminating stress concentration. This systematic approach combines vehicle body optimization principles with the specialized requirements of fabric unloading vehicles, enhancing their performance and structural integrity in industrial applications. system-level optimization method, this paper optimizes the vehicle body of the fabric unloading vehicle, finds the most dangerous working condition under 5 working conditions, and then carries out topology optimization to achieve the design of equal strength, lightweight and high stability of the vehicle body. After simulation verification, according to the comparison results, it is shown that after optimization, the first five order natural frequency of the vehicle body is significantly increased, which reduces the potential risk of the falling vehicle being affected by vibration during driving, and thus improves the stability of the vehicle body. The optimized vehicle body uses less material under the same load, while its strength, stiffness and stability are significantly improved. Compared to the original design, the optimized solution not only achieves a 32.5% reduction in vehicle body weight. The static stiffness analysis results of the optimized vehicle body are compared. It can be seen that the maximum stress of the optimized vehicle body is reduced by 23.3%, which fully meets the allowable stress conditions and approaches to the allowable stress, thus improving the utilization rate of materials. After optimization, the maximum deformation of the vehicle body is reduced by 60.3%, and the maximum displacement of the frame is reduced by 9%, that is, the stiffness of the vehicle body is enhanced. This shows that the system level optimization scheme considering the loading condition is feasible.
Conclusion The proposed optimization method not only significantly improves the performance of the vehicle body structure, but also provides a new optimization idea for related fields, which has certain practical value and theoretical guidance. However, the specific details and complexity of the working conditions, may be ignored, resulting in the simulation results are not accurate enough, and the description has certain limitations. Therefore, in order to improve the accuracy of the research results, it is necessary to further explore the specific effects of specific conditions. Subsequently, more types and quantities of working conditions are considered, and the influence of factors such as different heights and angles is considered in the loading and unloading process, so as to simulate the actual working scene more comprehensively. At the same time, the load calculation process is refined, considering the influence of the power arm length, the shape of the hook, the friction between the hook and the cloth, etc., so as to simulate the actual loading situation more accurately. Furthermore, a more refined simulation model is introduced, such as considering the influence of factors such as the speed change of the cloth hook in the process of resetting, the friction between the fabric and the fabric cart, so as to improve the accuracy of the simulation and make the optimized results more accurate and reasonable.

Key words: vehicle body structure, lightweight, mechanical analysis, multiple load cases, topology optimization, simulation analysis, fabric unloading vehicle

中图分类号: 

  • TH122

图1

落布车样图"

图2

落布车布局简图"

图3

受载工况图"

表1

7种不同工况约束和载荷情况"

工况
类型		 方向约束 载荷施加
前万向轮 后万向轮 差速轮
装载工况 X,Y X,Y Y,Z Y轴方向上1.2倍
全局载荷
横移工况 X,Y X,Y X,Y Y轴方向上全局载荷
制动工况 X,Y,Z X,Y,Z X,Y,Z Y轴方向上全局载荷
卸载工况 Y,Z Y,Z Y,Z Y轴方向上全局载荷
转弯工况 Y,Z Y,Z Y Y轴方向上全局载荷
加速 YZ Y YZ Y轴全局载荷和
X轴上惯性量
减速 YZ YZ YZ Y轴全局载荷和
X轴上惯性量

图4

装载工况有限元求解结果图"

图5

静态分析点集分布图"

表2

7种不同工况下车身结构静力学仿真校验"

工况类型 最大变
形量/mm		 最大等效
应力/MPa		 最大位
移量/mm
装载工况 0.000 68 201.3 0.327
横移工况 0.000 57 167.9 0.273
制动工况 0.000 54 167.1 0.267
卸载工况 0.000 56 151.9 0.269
转弯工况 0.000 55 151.9 0.269
加速 0.000 46 139.4 0.227
减速 0.000 36 111.7 0.178

表3

7种工况影响权重"

工况类型 权重
装载工况 0.311
横移工况 0.159
制动工况 0.130
卸载工况 0.128
转弯工况 0.123
加速 0.086
减速 0.063

图6

模态分析下车身模态振型图"

表4

车身前5阶固有频率及振型"

阶数i 固有频率/Hz 对应振型
1 56.73 局部侧弯
2 56.94 局部侧弯
3 70.01 局部侧弯
4 70.65 局部侧弯
5 82.30 局部侧向扭转

图7

优化后车身模态振型图"

表5

优化前后车身的前5阶固有频率对照"

阶数i 固有频率/Hz
优化前 优化后
1 16.73 159.72
2 56.94 169.87
3 70.01 180.14
4 70.65 185.81
5 82.50 207.67

图8

优化后车身有限元求解结果图"

表6

优化前后车身静态刚度分析结果"

类型 最大变
形量/mm		 最大
应力/MPa		 最大位
移量/mm
优化前 0.000 68 201.3 0.327
优化后 0.000 27 154.4 0.300
变化率/% -60.3 -23.3 -9

图9

经验设计落布车结构图"

表7

经验法与本文优化法设计的车身参数比较"

类型 质量/kg 长/m 宽/m 高/m
经验设计 34.133 1.30 0.52 0.200
本文优化设计 19.095 1.12 0.76 0.008

表8

经验法与本文优化法设计的稳定性参数比较"

类型 落布车重心
高度/mm		 车身宽
长比		 车身最大负载
变形量/mm
经验设计 227.51 0.40 0.026 00
本文优化设计 156.50 0.68 0.000 68

表9

车身前5阶固有频率及模态形状对照"

阶数i 经验设计
固有频率/Hz		 模态形状 本文优化设计
固有频率/Hz		 模态形状
1 34.15 局部侧弯 159.72 整体扭转
2 63.76 局部侧弯 169.87 整体扭转
3 70.46 局部扭转 180.14 整体侧弯
4 81.33 局部扭转 185.81 整体侧弯
5 89.43 局部侧弯扭转 207.67 整体侧弯
扭转
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