振动与冲击
振動與遲擊
진동여충격
JOURNAL OF VIBRATION AND SHOCK
2014年
4期
185-189,198
,共6页
史冬岩%石先杰%王青山%李文龙%谷静静
史鼕巖%石先傑%王青山%李文龍%穀靜靜
사동암%석선걸%왕청산%리문룡%곡정정
T型耦合板结构%改进傅里叶级数%任意边界条件%能量法
T型耦閤闆結構%改進傅裏葉級數%任意邊界條件%能量法
T형우합판결구%개진부리협급수%임의변계조건%능량법
T-coupled plate%Improved Fourier Series Method (IFSM)%general boundary condition%energy method
以T型耦合板为研究对象,在同时考虑面内振动和面外振动条件下采用改进傅里叶级数方法(Improved Fourier Series Method,IFSM)对其自由振动特性进行了计算分析。板结构的面内振动和面外振动位移函数表示为改进傅里叶级数形式,并引入正弦傅里叶级数以解决边界的不连续或跳跃现象。将位移函数的级数展开系数作为广义坐标,采用Rayleigh-Ritz方法对其进行求解。通过对不同边界条件及耦合连接情况下T型板自由振动特性进行计算,并将之与有限元法结果相比较,验证了该方法的正确性和有效性,为耦合板结构的振动控制提供可靠的理论依据。
以T型耦閤闆為研究對象,在同時攷慮麵內振動和麵外振動條件下採用改進傅裏葉級數方法(Improved Fourier Series Method,IFSM)對其自由振動特性進行瞭計算分析。闆結構的麵內振動和麵外振動位移函數錶示為改進傅裏葉級數形式,併引入正絃傅裏葉級數以解決邊界的不連續或跳躍現象。將位移函數的級數展開繫數作為廣義坐標,採用Rayleigh-Ritz方法對其進行求解。通過對不同邊界條件及耦閤連接情況下T型闆自由振動特性進行計算,併將之與有限元法結果相比較,驗證瞭該方法的正確性和有效性,為耦閤闆結構的振動控製提供可靠的理論依據。
이T형우합판위연구대상,재동시고필면내진동화면외진동조건하채용개진부리협급수방법(Improved Fourier Series Method,IFSM)대기자유진동특성진행료계산분석。판결구적면내진동화면외진동위이함수표시위개진부리협급수형식,병인입정현부리협급수이해결변계적불련속혹도약현상。장위이함수적급수전개계수작위엄의좌표,채용Rayleigh-Ritz방법대기진행구해。통과대불동변계조건급우합련접정황하T형판자유진동특성진행계산,병장지여유한원법결과상비교,험증료해방법적정학성화유효성,위우합판결구적진동공제제공가고적이론의거。
Here,an analytical method,the improved Fourier series method (IFSM)was presented for the free vibration analysis of a T-coupled plate with general boundary conditions.The in-plane vibration and out-of-plane vibration were taken into account via four types of coupling springs of arbitrary stiffnesses.Regardless of boundary conditions,the transverse and in-plane vibration displacement functions were taken as a new form of trigonometric expansion with accelerated convergence. The displacement functions could overcome all the relevant discontinuities of the elastic boundaries.The expansion coefficients were considered as the generalized coordinates,and they were determined using Rayleigh-Ritz method.The free vibration analysis of the T-coupled plate with various boundary and coupling conditions was performed using the proposed method.The reliability and accuracy of the proposed method were validated with the FEM results.This study provided a reliable and theoretical basis for vibration control of coupled plate structures.