振动与冲击
振動與遲擊
진동여충격
Journal of Vibration and Shock
2015年
21期
124-128,143
,共6页
舒红宇%罗霜%汪明明%陈齐平
舒紅宇%囉霜%汪明明%陳齊平
서홍우%라상%왕명명%진제평
液力减振器%空程冲击%有限元分析%流固耦合
液力減振器%空程遲擊%有限元分析%流固耦閤
액력감진기%공정충격%유한원분석%류고우합
hydraulic shock absorber%oil-loss-travel impact%finite element analysis%fluid-structure interaction
液力减振器内部的振动及冲击是其噪声产生的原因,通过实验和理论分析发现,该振动与冲击主要表现为空程冲击。为揭示液力减振器油液与活塞之间的空程冲击的具体过程和机理,首先通过建立数学模型,计算得到了某一减振器在不同激励下的空程距离;然后采用 ADINA 软件建立了模拟该减振器空程冲击过程的气-液两相有限元模型,并进行了流固耦合动态仿真;最后分析了活塞杆加速度的时域和频域响应。研究结果显示:流通阀阀片打开瞬间,油液与活塞的空程冲击将使活塞杆产生显著的轴向振动;随着空程距离增大,活塞杆轴向振动越明显。仿真计算结果与减振器噪声实验结果相符,表明该模型理论及其计算方法可解释减振器噪声产生的原因,并为降噪提供参考。
液力減振器內部的振動及遲擊是其譟聲產生的原因,通過實驗和理論分析髮現,該振動與遲擊主要錶現為空程遲擊。為揭示液力減振器油液與活塞之間的空程遲擊的具體過程和機理,首先通過建立數學模型,計算得到瞭某一減振器在不同激勵下的空程距離;然後採用 ADINA 軟件建立瞭模擬該減振器空程遲擊過程的氣-液兩相有限元模型,併進行瞭流固耦閤動態倣真;最後分析瞭活塞桿加速度的時域和頻域響應。研究結果顯示:流通閥閥片打開瞬間,油液與活塞的空程遲擊將使活塞桿產生顯著的軸嚮振動;隨著空程距離增大,活塞桿軸嚮振動越明顯。倣真計算結果與減振器譟聲實驗結果相符,錶明該模型理論及其計算方法可解釋減振器譟聲產生的原因,併為降譟提供參攷。
액력감진기내부적진동급충격시기조성산생적원인,통과실험화이론분석발현,해진동여충격주요표현위공정충격。위게시액력감진기유액여활새지간적공정충격적구체과정화궤리,수선통과건립수학모형,계산득도료모일감진기재불동격려하적공정거리;연후채용 ADINA 연건건립료모의해감진기공정충격과정적기-액량상유한원모형,병진행료류고우합동태방진;최후분석료활새간가속도적시역화빈역향응。연구결과현시:류통벌벌편타개순간,유액여활새적공정충격장사활새간산생현저적축향진동;수착공정거리증대,활새간축향진동월명현。방진계산결과여감진기조성실험결과상부,표명해모형이론급기계산방법가해석감진기조성산생적원인,병위강조제공삼고。
The generation of hydraulic shock absorber noise is the result of its inner vibration and impact.It is clear that the oil-loss-travel impact is the main behavior of its vibration and impact by means of theoretical analysis and tests.In order to reveal the specific process and mechanism for the oil-loss-travel impact between oil fluid and piston of a hydraulic shock absorber,firstly the oil-loss-travel distance under different excitations for a certain shock absorber was calculated through building its mathematical model.And then,the two-phase gas-oil finite element model for simulating the oil-loss-travel impact of the hydraulic shock absorber was established with ADINA and its fluid-structure interaction dynamic simulation was conducted.The responses of its piston rod in time domain and frequency domain were analyzed. The results showed that the significant axial vibration of the piston-rod is caused by the oil-loss-travel impact between oil fluid and piston at the moment for opening of circulating valve;with increase in oil-loss-travel distance,the axial vibration of the piston rod grows.The simulation results agreed well with those of the hydraulic shock absorber noise tests,it was shown that the model theory and its calculation method can explain the cause of the hydraulic shock absorber noise,and provide a reference for noise reduction.