考虑多场景的空调器包装泡沫动力学仿真及结构优化分析

doi:10.19784/j.cnki.issn1672-0172.2025.99.104

摘要/Abstract

摘要： 面对全球绿色低碳转型与包装环保法规,空调行业传统泡沫缓冲包装的资源消耗、回收及污染问题日益凸显。为践行绿色包装原则,聚焦空调高端柜机包装方案,综合运用材料性能实验测试与仿真技术,实现了泡沫缓冲性能提升与材料绿色轻量化的双重目标。首先,研究了发泡聚苯乙烯（EPS）的关键力学与能量特性,建立其应力-应变本构模型。然后,基于复杂的物流场景,建立整机、泡沫缓冲结构及瓦楞纸箱的仿真模型,通过实验验证模型准确性,然后建立了跌落仿真问题评价标准。结果表明：跌落、夹持仿真结果与实验结果一致性好,其次,在非传力路径进行减料,最终在保持运输性能前提下优化后泡沫可实现材料用量削减27 g,夹持吸能量提升35%,跌落吸能量提升8%。显著降低碳排放及改模次数。证明了仿真技术在绿色缓冲包装设计中的核心价值,为空调行业包装创新升级提供可行思路。

关键词: EPS泡沫, 绿色包装, 显示动力学, 跌落仿真, 夹持仿真, 空调包装

Abstract: Facing the global transition to green and low-carbon practices alongside environmental packaging regulations, the traditional foam cushioning packaging in the air conditioning industry is increasingly revealing issues related to resource consumption, recycling, and pollution. To adhere to green packaging principles and focus on packaging solutions for high-end cabinet air conditioners, a comprehensive application of material performance testing and simulation technology has been achieved, realizing the dual goals of enhancing foam cushioning performance and achieving green, lightweight materials. First, the key mechanical and energy absorption properties of expanded polystyrene (EPS) were systematically investigated, and its stress-strain constitutive model was established. Subsequently, a comprehensive simulation model encompassing the complete unit, foam cushioning structure, and corrugated carton was developed based on complex logistics scenarios. The model’s accuracy was validated through experiments, and evaluation criteria for drop simulation were established. The results demonstrate strong consistency between the drop/clamp simulation outcomes and experimental data, with simulations effectively identifying potential weak points in advance and enabling structural optimization during the design phase. Furthermore, material reduction was implemented in non-load-bearing paths. The optimized foam structure achieved a 27 g reduction in material usage while maintaining transportation performance, alongside a 35% improvement in clamping energy absorption and an 8% increase in drop impact energy absorption. This approach significantly reduces carbon emissions and minimizes mold modification cycles. So validating the critical role of simulation technology in green cushioning packaging design and providing a feasible pathway for innovative packaging upgrades in the air conditioning industry.

Key words: EPS foam, Green packaging, Explicit dynamics, Drop simulation, Clamping simulation, Air conditioner packaging

中图分类号:

TM925
TB6

赵天阳, 高旭, 熊军, 李嘉辉, 李帅, 杨俊涛. 考虑多场景的空调器包装泡沫动力学仿真及结构优化分析[J]. 家电科技, 2025, 0(zk): 503-507.

ZHAO Tianyang, GAO Xu, XIONG Jun, LI Jiahui, LI Shuai, YANG Juntao. Dynamic simulation and structural optimization analysis of AC packaging foam considering multiple scenarios[J]. Journal of Appliance Science & Technology, 2025, 0(zk): 503-507.

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