Influences of nonlinear parameters on the performance of a free-piston Stirling engine

This study presents a thermodynamic-dynamic model of a free-piston Stirling engine (FPSE) with nonlinear coefficients of spring, load damping, and pressure for working spaces. The effects of the nonlinear coefficients of hardening and softening springs on the movement and operating frequency of a displacer and piston are investigated. Subsequently, the influences of the nonlinear pressure terms of the working space and buffer spaces, as well as the nonlinear coefficients of the load on the amplitudes of the two pistons, frequency, and output powers are discussed. The results indicate that the low nonlinear coefficients of the spring have a minor effect on the amplitudes and frequency. As the high nonlinear coefficients of the hardening spring increase, the amplitudes and output power decrease, while the frequency increases. As the nonlinear terms of the softening spring increase, the amplitudes and output power reach maximum values, but the frequency is reduced by 3.55%. The effects of the nonlinear pressure terms on the amplitudes and output power are not evident. However, an increase in the nonlinear load leads to a significant decrease in the FPSE's performance. This study presents a thermodynamic-dynamic model of a free-piston Stirling engine (FPSE) with nonlinear coefficients of spring, load damping, and pressure for working spaces. The results show that as the high nonlinear coefficients of the hardening spring increase, the amplitude and output power decrease, while the frequency increases. As the nonlinear terms of the softening spring increase, the amplitudes and output power reach maximum values, but the frequency is decreased. An increase in the nonlinear load led to a significant decrease in the FPSE's performance.image

Automated summary

This study presents a thermodynamic-dynamic model of a free-piston Stirling engine (FPSE) and investigates the effects of nonlinear coefficients on the engine's performance. The results show that the high nonlinear coefficients of the hardening spring decrease the amplitude and output power while increasing the frequency. On the other hand, the nonlinear terms of the softening spring increase the amplitude and output power but decrease the frequency. The effects of nonlinear pressure terms are not significant, but an increase in the nonlinear load leads to a significant decrease in the engine's performance.