振动与冲击
振動與遲擊
진동여충격
JOURNAL OF VIBRATION AND SHOCK
2014年
13期
67-71
,共5页
张志勇%张义波%刘鑫%谢小平
張誌勇%張義波%劉鑫%謝小平
장지용%장의파%류흠%사소평
重型卡车%结构噪声%板件贡献度%声-固耦合%噪声预测
重型卡車%結構譟聲%闆件貢獻度%聲-固耦閤%譟聲預測
중형잡차%결구조성%판건공헌도%성-고우합%조성예측
heavy-duty truck%structure-borne noise%acoustic contribution%acoustic-structure coupling%noise pre-diction
为了确定驾驶室内哪些板件对驾驶员的耳旁噪声影响最大,首先建立了重型卡车驾驶室有限元模型,通过比较分析计算模态和试验模态验证了其精度;在此基础上建立了驾驶室声-固耦合模型,进行了耦合模态分析,得到了声场和结构的耦合效应;以实车工况测试的驾驶室4个悬置加速度信号作为模型外部激励输入,基于耦合有限元法对驾驶员耳旁噪声进行了预测,通过与试验测试值对比进一步验证了驾驶室声-固耦合模型的精度;最后进行了板件贡献量和结构模态参与因子分析,确定了对驾驶员耳旁峰值声压贡献最大的板件,并通过对比分析板件厚度优化前后的噪声声压,验证了分析结果的正确性。
為瞭確定駕駛室內哪些闆件對駕駛員的耳徬譟聲影響最大,首先建立瞭重型卡車駕駛室有限元模型,通過比較分析計算模態和試驗模態驗證瞭其精度;在此基礎上建立瞭駕駛室聲-固耦閤模型,進行瞭耦閤模態分析,得到瞭聲場和結構的耦閤效應;以實車工況測試的駕駛室4箇懸置加速度信號作為模型外部激勵輸入,基于耦閤有限元法對駕駛員耳徬譟聲進行瞭預測,通過與試驗測試值對比進一步驗證瞭駕駛室聲-固耦閤模型的精度;最後進行瞭闆件貢獻量和結構模態參與因子分析,確定瞭對駕駛員耳徬峰值聲壓貢獻最大的闆件,併通過對比分析闆件厚度優化前後的譟聲聲壓,驗證瞭分析結果的正確性。
위료학정가사실내나사판건대가사원적이방조성영향최대,수선건립료중형잡차가사실유한원모형,통과비교분석계산모태화시험모태험증료기정도;재차기출상건립료가사실성-고우합모형,진행료우합모태분석,득도료성장화결구적우합효응;이실차공황측시적가사실4개현치가속도신호작위모형외부격려수입,기우우합유한원법대가사원이방조성진행료예측,통과여시험측시치대비진일보험증료가사실성-고우합모형적정도;최후진행료판건공헌량화결구모태삼여인자분석,학정료대가사원이방봉치성압공헌최대적판건,병통과대비분석판건후도우화전후적조성성압,험증료분석결과적정학성。
In order to determine which panels in cab influence the driver’s ear noise greatly,a finite element model of heavy-duty truck cab was established,and its accuracy was verified by comparing the computational modal and the experimental modal.On this basis an acoustic-solid coupling model of the cab was built and the coupling effect between sound and structure was obtained by using the method of coupling modal analysis.Then the driver’s ear noise was predicted based on the coupled finite element method,in which the external excitation inputs,that is,the acceleration signals of four cab suspensions,in the acoustic-solid coupling model were sampled from a real vehicle driving test.The comparison of the test value and predictive value further verifies the accuracy of the acoustic-solid coupling model. Finally,the panel contribution and the modal participation factor analysis were implemented,by which the panels that have the largest contribution to the peak pressure of the driver’s ear noise were identified.The validity of the conclusions were verified by a comparison of the different driver’s ear noise pressures,sampled before and after the optimization of the panels thickness.