Study on the Mechanical Properties and Energy Absorbing Capability of Polyurethane Microcellular Elastomers under Different Compressive Strain Rates

Polyurethane microcellular elastomers (PUME) are good at impact protection and energy absorption, and belong to rate sensitive- and strain history-dependent materials. In this study, PUME with different densities of 800 kg/m(3), 600 kg/m(3) and 400 kg/m(3) were prepared, then the compressive responses of PUME in the strain rate range of 0.001 s(-1) to 3400 s(-1) were systemically investigated. By studying the energy absorption and efficiency diagram of PUME, the compressive properties of materials with different densities under compressive impact load were described, which showed that PUME with a density of 600 kg/m(3) had better performance. A visco-hyperelasticity-air constitutive model was established to describe the large deformation response of PUME at high strain rates. The model included three components: hyperelastic part, viscoelastic part and gas pressure part. Quasi-static and dynamic compression tests were used to determine the constitutive relations of seven parameters. The samples with a density of 600 kg/m(3) at different strain rates were fitted by MATLAB software, and the constitutive model parameters were obtained. The comparison between the constitutive equation and the experimental results showed that there was a good consistency. The constitutive model can provide data support for simulation analysis and application of PUME as energy absorbing protective facilities.

Automated summary

This study systematically investigates the compressive responses of polyurethane microcellular elastomers (PUME) with different densities (800 kg/m(3), 600 kg/m(3), and 400 kg/m(3)) under various strain rates. The compressive properties of PUME with different densities under compressive impact load are described, and it is found that PUME with a density of 600 kg/m(3) exhibits better performance. A visco-hyperelasticity-air constitutive model is established to describe the large deformation response of PUME at high strain rates. The constitutive model parameters are obtained and validated through experimental results, and it can provide data support for the simulation analysis and application of PUME as energy absorbing protective facilities.