材料科学
极限抗拉强度
聚丙烯
复合材料
造型(装饰)
抗弯强度
残余应力
注塑成型
析因实验
弯曲
聚合物
实验设计
过程变量
工作(物理)
艾氏冲击强度试验
制造工艺
压力(语言学)
拉伸试验
残余物
吹塑
响应面法
还原(数学)
注塑机
材料性能
模具
作者
Jorge Jiménez-Armendáriz,Andrea Guevara-Morales,Ulises Figueroa-López,Mariel Alfaro-Ponce,José Martínez-Trinidad,Moises Jimenez-Martinez
摘要
Injection molding is a high-volume manufacturing process widely used for producing polymer components; however, its process parameters strongly influence residual stress, warpage, and the resulting mechanical performance. This work presents a comprehensive factorial design and ANOVA to evaluate the simultaneous effects of the injection temperature, packing pressure, packing time, and specimen orientation on the warpage, hardness, tensile, and flexural properties of polypropylene plates. The results demonstrate that the injection temperature and packing pressure are the dominant factors affecting the hardness and ultimate tensile strength, whereas warpage is mainly governed by the injection temperature and orientation. Under the tested conditions, certain combinations of injection temperature and packing pressure led to an improved mechanical performance; however, these adjustments also produced reductions in other properties, indicating that the balance among parameters depends on the targeted application rather than a single optimal set. Conversely, the parameter combination that produced the lowest warpage still yielded a significant increase in Esec, indicating that reducing the warpage does not necessarily compromise the tensile stiffness. Interestingly, variations in the stress distribution between the tensile and bending tests suggest that the solidification-induced structure of the material influences its mechanical response, with specimens that showed a lower tensile strength exhibiting a comparatively higher resistance under bending. These findings provide new insights into the trade-offs between dimensional accuracy and mechanical performance and offer practical guidelines for optimizing polypropylene injection molding processes.
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