Content optimization of polyphenylene sulfide composites filled with carbon fibers of different size

N. Grishaeva, S. Bochkareva, S. Panin, Le Thi My Hiep, B. Lyukshin, I. Panov, Nguen Duc Ahn
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Abstract

The chemical content of polyphenylene sulfide (PPS) based composite with specified physical–mechanical properties is determined in the study with the use of experimental data on the dependence of effective properties (volumetric wear, elastic modulus, elongation at break, etc.) versus the values of control parameters. The latter are degree of filling with (i) Short Carbon Fibers (SCF) of ∼70 µm long and (ii) Chopped Carbon Fibers (CCF) ∼2 mm long. After the required number of experimental reference points has been determined the technique for data supplementation up to a regular numerical array with the use of linear interpolation is employed. The obtained dependences of the effective properties versus the control parameter values are constructed in the form of surfaces and corresponding isolines. At the contour plots, a region with the required effective properties is then highlighted. Since the regions overlap each other, their intersection determines the allowable control parameters range that impart the required values to the effective properties. The possibility to design filled polymer materials with a complex of predefined strain-strength and tribological properties is demonstrated. The experimental results are used to gain the reference points in contrast to the previously used approach when a set of computational experiment data were employed. On the one hand, the combination of a full-scale laboratory and computational experiments makes the process of modeling and design materials more evident, clear and reasonable from a physical point of view. On the other hand, it allows to interpret the results as more reliable, as well as less time and material consuming.The chemical content of polyphenylene sulfide (PPS) based composite with specified physical–mechanical properties is determined in the study with the use of experimental data on the dependence of effective properties (volumetric wear, elastic modulus, elongation at break, etc.) versus the values of control parameters. The latter are degree of filling with (i) Short Carbon Fibers (SCF) of ∼70 µm long and (ii) Chopped Carbon Fibers (CCF) ∼2 mm long. After the required number of experimental reference points has been determined the technique for data supplementation up to a regular numerical array with the use of linear interpolation is employed. The obtained dependences of the effective properties versus the control parameter values are constructed in the form of surfaces and corresponding isolines. At the contour plots, a region with the required effective properties is then highlighted. Since the regions overlap each other, their intersection determines the allowable control parameters range that impart t...
不同尺寸碳纤维填充聚苯硫醚复合材料的含量优化
在研究中,利用有效性能(体积磨损、弹性模量、断裂伸长率等)与控制参数值的依赖关系的实验数据,确定了具有特定物理力学性能的聚苯硫醚(PPS)基复合材料的化学含量。后者是指(i)短碳纤维(SCF) (~ 70 μ m长)和(ii)短切碳纤维(CCF) (~ 2mm长)的填充程度。在确定了所需的实验参考点数量之后,采用线性插值技术将数据补充到常规数值阵列。得到的有效性质对控制参数值的依赖关系以曲面和相应等值线的形式构造。在等高线图上,具有所需有效属性的区域将被突出显示。由于区域相互重叠,因此它们的交集决定了允许的控制参数范围,该范围将所需的值赋予有效属性。证明了设计具有预定义应变强度和摩擦学性能的复合填充聚合物材料的可能性。在采用一组计算实验数据的情况下,采用实验结果来获得参考点,而不是采用以往的方法。一方面,全尺寸实验室与计算实验相结合,使材料的建模和设计过程从物理角度上更加明显、清晰、合理。另一方面,它允许将结果解释为更可靠,以及更少的时间和材料消耗。在研究中,利用有效性能(体积磨损、弹性模量、断裂伸长率等)与控制参数值的依赖关系的实验数据,确定了具有特定物理力学性能的聚苯硫醚(PPS)基复合材料的化学含量。后者是指(i)短碳纤维(SCF) (~ 70 μ m长)和(ii)短切碳纤维(CCF) (~ 2mm长)的填充程度。在确定了所需的实验参考点数量之后,采用线性插值技术将数据补充到常规数值阵列。得到的有效性质对控制参数值的依赖关系以曲面和相应等值线的形式构造。在等高线图上,具有所需有效属性的区域将被突出显示。由于区域相互重叠,它们的交集决定了允许的控制参数范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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