At room temperature, the impact of strain rates on the damage of CVPC compound

The demand of polymers has been increasing over the past decade, due to their specific properties. This large use leads mechanical engineers to study material damage problems. Partial or total ruptures resulting from these problems frequently cause accidents. Unfortunately, such incidents occur frequently due to insufficient understanding of the operating conditions or the types of damage. This paper presents the impact of strain rate on the damage of chlorinated polyvinyl chloride compounds. Tensile tests were conducted on the samples at room temperature with three strain rates (5, 50, and 500 mm/min). The results of the tests are used to develop two damage models for this polymer: the first one generated through static damage and the second one acquired via the use of unified theory. Both models are constructed on the concept of stress. The results clearly obtained from these two models enable us to describe the mechanical comportment of chlorinated polyvinyl chloride and to forecast how the damage will develop. Moreover, three stages of damage are identified to assist predictive maintenance in defining the material CPVC's safety and maintenance intervals.

Automated summary

The demand for polymers has been increasing over the past decade due to their unique properties. This has led mechanical engineers to study material damage problems, as partial or total ruptures resulting from these problems often cause accidents. This paper investigates the impact of strain rate on the damage of chlorinated polyvinyl chloride compounds through tensile tests conducted at different strain rates. Two damage models are developed based on the concept of stress, which enable the description and prediction of the mechanical behavior and damage development of chlorinated polyvinyl chloride.