Abstract
To describe the effect of confining pressure on the mechanical responses of N15 propellant, a constitutive model considering the confining pressure effect was first established for N15 propellant based on the elastic-viscoelastic correspondence principle. Then, the mechanical properties of N15 solid propellant under different confining pressures were obtained using confining pressure test system, and the obtained results indicate that the initial modulus of propellant did not change with confining pressure, but the maximum tensile strength, rupture strength, the maximum elongation, and elongation at break increased with increasing confining pressure. In conjunction with propellants’ mesoscopic structure and cross-section analysis, the mechanical mechanism of confining pressure effect on propellant was initially disclosed. Due to confining pressure, the particle dewetting inside the propellant was reduced, the hole propagation was delayed, and crack extension inhibited germination, proving that confining pressure has a strengthening impact on the propellant. Finally, assuming that the model parameters were dependent on pressure, the model parameters acquisition and validation were conducted. The results demonstrated that constitutive model can describe confining pressure influence on the mechanical properties of N15 propellant accurately.
Highlights
The mechanical properties of solid propellants under complex loads are essential as a support and basis to study charge structure integrity
A few nonlinear viscoelastic constitutive models of composite solid propellant under atmospheric pressure were proposed by Xu et al [7], Peng et al [8], and Ma et al [9]
We introduced a nonlinear viscoelastic constitutive model to model the effect of confining pressure and the method of model parameters acquisition was presented
Summary
The mechanical properties of solid propellants under complex loads are essential as a support and basis to study charge structure integrity. By studying the nonlinear mechanical properties of composite solid propellants, a damage-containing thermoviscous elastic constitutive model was established, and the material function at different temperatures was unified to a reference temperature using conversion time. International Journal of Aerospace Engineering the structural integrity of charge under ignition and pressurization using propellant mechanical characteristics under atmospheric pressure. In the finite strain model framework of Simo [15], Tunç, and Özüpek [16, 17] developed the three-dimensional viscoelastic constitutive model under confining pressure environment by introducing the damage evolution model of Canga et al [18] and carried out the finite element secondary development to expand the application. It is believed that this work will lay a foundation for analyzing the structural integrity of charge under the ignition shock and pressure load of a solid rocket engine
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