Numerical and Experimental Investigation of Nano zinc Oxide's Effect on the Mechanical Properties of Chloroprene and Natural Rubber (CR/NR) Composites

Emad Kadum Njim; Fadhel Abbas Hadi; Mohsin Noori Hamzah; Naeem Abdulmohsin Alhilo; Mohammed Hamza  Al-Maamori

doi:10.15330/pcss.25.1.14-25

Authors

Emad Kadum Njim Ministry of Industry and Minerals, State Company for Rubber and Tires Industries, Iraq
Fadhel Abbas Hadi Mechanical Engineering Department, University of Technology, Iraq
Mohsin Noori Hamzah Mechanical Engineering Department, University of Technology, Iraq
Naeem Abdulmohsin Alhilo Ministry of Industry and Minerals, State Company for Rubber and Tires Industries, Iraq
Mohammed Hamza Al-Maamori Biomedical Engineering Department, Faculty of Engineering, University of Al-Mustaqbal, Iraq

DOI:

https://doi.org/10.15330/pcss.25.1.14-25

Keywords:

Natural rubber, Chloroprene Rubber, Nanoparticles, Mechanical properties, Hyperelastic models

Abstract

Nanocomposites, especially natural rubber (NR), have been extensively studied for their unique features and superior performance in tire applications. The present research investigated the impact of zinc oxide nanoparticles (ZnO) on the performance of typical rotary machine seals made of chloroprene rubber / natural rubber (CR/NR) composites. An ordinary standard rubber two-roll mill and hydraulic press were used to prepare high-temperature vulcanized CR/NR samples filled with ZnO nanoparticles. Tensile strength, tear resistance, abrasion resistance, resilience, and hardness were measured to determine the effects of nanoparticles on these physical and mechanical properties. Based on the various hyperelastic modeling schemes, enhancement in multiple characteristics of the control sample, such as overhaul properties, was observed. Furthermore, results show that increasing nanoparticle content in the vulcanisates increased the physicomechanical characteristics, such as hardness, resilience, tensile strength, and elastic Modulus at 200% strain. Moreover, hyperelastic analytical modeling shows that the differences with experimental results are less than 5%.

Author Biographies

Fadhel Abbas Hadi, Mechanical Engineering Department, University of Technology, Iraq

Mohsin Noori Hamzah, Mechanical Engineering Department, University of Technology, Iraq

Naeem Abdulmohsin Alhilo, Ministry of Industry and Minerals, State Company for Rubber and Tires Industries, Iraq

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