农业工程学报
農業工程學報
농업공정학보
2013年
16期
66-73
,共8页
刘厚林%丁剑%谈明高%崔建保%王勇
劉厚林%丁劍%談明高%崔建保%王勇
류후림%정검%담명고%최건보%왕용
泵%噪声%振动%叶轮出口宽度%大涡模拟
泵%譟聲%振動%葉輪齣口寬度%大渦模擬
빙%조성%진동%협륜출구관도%대와모의
pumps%acoustic noise%vibrations%impeller outlet width%large eddy simulation
为研究叶轮出口宽度对离心泵在水动力激励下泵壳振动辐射噪声的影响,该文以一台单级单吸离心泵为研究对象,保持泵体和叶轮其他几何参数不变,运用FEM\BEM(finite element method\boundary element method)声振耦合计算和试验测量方法进行了叶轮出口宽度分别为10、8和12 mm的噪声辐射分析。采用大涡模拟方法对离心泵内部瞬态流场进行计算,得到蜗壳壁面偶极子声源。在对泵壳体结构进行模态分析的基础上,利用 LMS Virtual Lab的间接边界元IBEM声振耦合模块计算非定常流动引起的离心泵内部噪声,并进行了试验验证,在此基础上,对离心泵外场噪声及其声辐射进行计算,并研究了叶轮出口宽度对离心泵外场噪声辐射的影响。结果表明,离心泵叶片通过频率处的辐射声功率随着叶轮出口宽度的增大而增大;叶轮出口宽度存在一个合适的取值范围,使得各流量工况下外场噪声声压级较小;综合考虑离心泵能量性能与外场噪声,叶轮出口宽度为10 mm时,离心泵综合性能较优。研究结果可为低振动低噪声离心泵的水力优化设计提供参考。
為研究葉輪齣口寬度對離心泵在水動力激勵下泵殼振動輻射譟聲的影響,該文以一檯單級單吸離心泵為研究對象,保持泵體和葉輪其他幾何參數不變,運用FEM\BEM(finite element method\boundary element method)聲振耦閤計算和試驗測量方法進行瞭葉輪齣口寬度分彆為10、8和12 mm的譟聲輻射分析。採用大渦模擬方法對離心泵內部瞬態流場進行計算,得到蝸殼壁麵偶極子聲源。在對泵殼體結構進行模態分析的基礎上,利用 LMS Virtual Lab的間接邊界元IBEM聲振耦閤模塊計算非定常流動引起的離心泵內部譟聲,併進行瞭試驗驗證,在此基礎上,對離心泵外場譟聲及其聲輻射進行計算,併研究瞭葉輪齣口寬度對離心泵外場譟聲輻射的影響。結果錶明,離心泵葉片通過頻率處的輻射聲功率隨著葉輪齣口寬度的增大而增大;葉輪齣口寬度存在一箇閤適的取值範圍,使得各流量工況下外場譟聲聲壓級較小;綜閤攷慮離心泵能量性能與外場譟聲,葉輪齣口寬度為10 mm時,離心泵綜閤性能較優。研究結果可為低振動低譟聲離心泵的水力優化設計提供參攷。
위연구협륜출구관도대리심빙재수동력격려하빙각진동복사조성적영향,해문이일태단급단흡리심빙위연구대상,보지빙체화협륜기타궤하삼수불변,운용FEM\BEM(finite element method\boundary element method)성진우합계산화시험측량방법진행료협륜출구관도분별위10、8화12 mm적조성복사분석。채용대와모의방법대리심빙내부순태류장진행계산,득도와각벽면우겁자성원。재대빙각체결구진행모태분석적기출상,이용 LMS Virtual Lab적간접변계원IBEM성진우합모괴계산비정상류동인기적리심빙내부조성,병진행료시험험증,재차기출상,대리심빙외장조성급기성복사진행계산,병연구료협륜출구관도대리심빙외장조성복사적영향。결과표명,리심빙협편통과빈솔처적복사성공솔수착협륜출구관도적증대이증대;협륜출구관도존재일개합괄적취치범위,사득각류량공황하외장조성성압급교소;종합고필리심빙능량성능여외장조성,협륜출구관도위10 mm시,리심빙종합성능교우。연구결과가위저진동저조성리심빙적수력우화설계제공삼고。
In order to better understand the effects of impeller outlet width on the flow-induced vibration and noise of centrifugal pumps, a single grade end suction centrifugal pump was chosen as research object. The impeller outlet width was varied from 8mm to 10mm and 12mm, while the volute and other geometric parameters were kept constant. The flow-induced noise of centrifugal pumps was studied experimentally and numerically. A FEM\BEM acoustic-vibration-coupling method was developed to study the effect of impeller outlet width on the centrifugal pump noise caused by the hydrodynamic forces. The developed method was validated and verified through experimental results. For the internal flow of pumps characterized by a small Mach number, the sound analysis of fluid was separated into the following two steps. The first step was a hydrodynamic analysis, which is a CFD simulation to be performed to obtain noise-generating fluid forces;in this step, the large eddy simulation method was used to solve the transient flow field of the pump, and a time series for the pressure fluctuations at the fluid–wall interface was obtained. The second step was hydroacoustic-vibration coupling analysis, which considers the solution of an inhomogeneous wave equation. The fluid pressure fluctuations obtained at the first step are fed to the pump case structure causing vibration of the outer casing surface vibrating, based on the elastic-wave propagation of the structure,the vibration velocities on the outer casing surface was simulated. And the acoustical simulation of noise emission to the environment was performed by FEM\BEM methods, in which the feedback influences of environmental noise on the structure and of structural vibration on the fluid were considered. In the second step, the modal of the pump casing structure was analyzed using the finite element method (FEM), and the acoustic noise caused by the unsteady flow of the pump was calculated by the acoustic-vibro coupling module of the Virtual Lab software. First, the interior noise fields were calculated and compared with experimental results, showing that the validation of the LES combined with the FEM\BEM methods for centrifugal pump noise computation was verified, and the FEM\BEM coupling methods was more accurate than the BEM uncoupling methods. On this basis, the outer sound fields were investigated, and the effect of impeller outlet width to outer sound fields was studied. The results show that the sound power at the blade passing frequency becomes larger as the impeller outlet width increases. In order to investigate the sound spatial distribution around pump, 36 monitoring points were arranged each 1 meter farther from the center of impeller, and noise directivity distribution was obtained by using FEM\BEM calculations. The noise directivity results show that the sound pressure level at the blade passing frequency becomes larger as the impeller outlet width increases, and the growth amplitude of the sound pressure level increases as the impeller outlet width increases. Considering the energy performance of the pump and the outer sound field, there exists a suitable impeller outlet width to ensure a better comprehensive performance of the pump. The research results are helpful for hydraulic optimization design of low vibration and low noise centrifugal pumps.