The two-dimensional nonlinear acoustic field of eleven exponential shaped res- onators was simulated with a computational fluid dynamics software Fluent. The influence of driving frequency and driving intensity on pre...The two-dimensional nonlinear acoustic field of eleven exponential shaped res- onators was simulated with a computational fluid dynamics software Fluent. The influence of driving frequency and driving intensity on pressure in resonator as well as its natural frequency was investigated. The relationship between natural frequency and theoretical calculation res- onance frequency was also explored. It is found that beating phenomena can be observed in the resonator when the driving frequency deviates from the natural frequency. Moreover, the natural frequency of resonator increases with the increasing of driving intensity, which shows a hard spring effect. However, the driving intensity plays little effect on natural frequency and the natural frequencies are smaller than the theoretical calculation values in any driving intensity. Meanwhile, a formula between the natural frequency and its first-order resonance frequency from theoretical calculation was obtained by linear fitting for all these exponential shaped resonators under consideration. It is also found that the highest pressure amplitude and highest pressure ratio can be obtained from the exponential shaped resonator of m = 2.8 under the same driving intensity. Moreover, the relation between natural frequency and the theoretical resonance frequency for m = 2.8-tube is slightly different from other tubes in consideration.展开更多
基金jointly supported by National Natural Science Foundation of China(51405157,51476052)Scientific Research Fund of Hunan Provincial Education Department(14C0433,14B057)
文摘The two-dimensional nonlinear acoustic field of eleven exponential shaped res- onators was simulated with a computational fluid dynamics software Fluent. The influence of driving frequency and driving intensity on pressure in resonator as well as its natural frequency was investigated. The relationship between natural frequency and theoretical calculation res- onance frequency was also explored. It is found that beating phenomena can be observed in the resonator when the driving frequency deviates from the natural frequency. Moreover, the natural frequency of resonator increases with the increasing of driving intensity, which shows a hard spring effect. However, the driving intensity plays little effect on natural frequency and the natural frequencies are smaller than the theoretical calculation values in any driving intensity. Meanwhile, a formula between the natural frequency and its first-order resonance frequency from theoretical calculation was obtained by linear fitting for all these exponential shaped resonators under consideration. It is also found that the highest pressure amplitude and highest pressure ratio can be obtained from the exponential shaped resonator of m = 2.8 under the same driving intensity. Moreover, the relation between natural frequency and the theoretical resonance frequency for m = 2.8-tube is slightly different from other tubes in consideration.
