振動噪音在近年來已成為產品設計的評估指標,在壓縮機同樣是非常重要的一環。本文提出一應用於迴轉式壓縮機之新型顆粒阻尼器(Particle Damper, PD)設計,以同時達到轉子動平衡及壓縮機抑振之效果。首先使用多體動力學建立迴轉式壓縮機模型,模型中考量循環氣體負載變化、支座與橡膠墊剛性與阻尼,模擬中同時應用離散元素法和多體動力學進行雙向耦合得到動態模擬結果,並透過實驗驗證在轉動頻率下的振動趨勢與量值,確認此模型之可靠性;後續利用此模型探討具PD之迴轉式壓縮機(新構型)之動平衡與抑振研究。此外,本研究針對新構型PD與原構型(頂配重塊)進行振動量測、紀錄比較其抑振效果,確認新構型確實有抑振效果;也探討在不同阻尼器槽數對壓縮機系統之抑振差異。隨顆粒摩擦係數增加,新構型系統之總動能越小,說明摩擦耗能越大,PD之抑振效果越佳;隨顆粒恢復係數增加,新構型之動能越大,說明碰撞耗能越小,PD之抑振效果越差。透過實驗確認振動數值,具六槽新構型阻尼器的壓縮機,其平均徑向位移可降低18.96 %、平均切向位移可降低3.74 %、平均徑向加速度可降低1.67 %、平均切向加速度可降低1.41 %,確認了本研究提出之顆粒阻尼器具有抑制振動之效果。;Vibration noise has become an evaluation index for product design in recent years, especially in compressor designs. In this paper, a new particle damper (PD) design in a rotary compressor is proposed to achieve both the rotor dynamic balancing of rotor and the vibration suppression of the compressor system. Firstly, a model of rotary compressor is established based on Multi-Body Dynamics (MBD), considering the variation of circulating gas load, stiffness and damping of bearings and rubber pads, Vibration trends and magnitudes for different rotational frequencies are experimentally verified. This model is further used to investigate the effects of dynamic balancing and vibration suppression for the rotary compressor with the PD (new configuration). In addition, the practical experiments are conducted to measure vibration signals of the rotary compressor with the proposed PD and with the original top counterweight. Further, influence of the PD with different groove numbers on the vibration suppression of rotary compressor system is discussed. Total kinetic energy for the new configuration system becomes smaller as increasing the frictional coefficient of particles, indicating that the effect of PD′s vibration suppression becomes better as the frictional energy consumption is getting greater. The kinetic energy of new configuration system becomes greater as increasing the restitution coefficient of particles, indicating that the effect of vibration suppression of PD becomes worse as the collision energy consumption reduces. Regarding to the measured data of Case 1, the average reduction on the radial displacement and the tangential displacement is 18.96% and 3.74%, respectively; the average reduction on the radial acceleration and the tangential acceleration is 1.67% and 1.41%, respectively. The effect of the proposed PD on vibration suppression is thus confirmed.
