南昌航空大学学报(自然科学版)
南昌航空大學學報(自然科學版)
남창항공대학학보(자연과학판)
JOURNAL OF NANCHANG HANGKONG UNIVERSITY(NATURAL SCIENCE EDITION)
2015年
1期
1-6
,共6页
层合板%动态非线性%固有频率%优化设计
層閤闆%動態非線性%固有頻率%優化設計
층합판%동태비선성%고유빈솔%우화설계
laminates%dynamic nonlinear%natural frequency%optimal design
分别采用经典薄板理论、一阶剪切变形理论及高阶剪切变形理论对复合材料层合板进行动态非线性分析。根据位移场导出层合板的虚应变能、虚动能及虚功,由虚位移原理得出层合板的控制方程。结合Navier三角函数解求出四边简支层合板的固有频率;将纤维铺设角、跨厚比、弹性模量比对固有频率的影响进行比较分析;基于高阶剪切变形理论,用改进的适应度函数遗传算法对复合材料层合板的固有频率进行优化设计。结果表明:同经典薄板理论和一阶剪切变形理论相比,高阶剪切变形理论更能精确地预报结构的固有频率,优化后的层合板固有频率明显提高。
分彆採用經典薄闆理論、一階剪切變形理論及高階剪切變形理論對複閤材料層閤闆進行動態非線性分析。根據位移場導齣層閤闆的虛應變能、虛動能及虛功,由虛位移原理得齣層閤闆的控製方程。結閤Navier三角函數解求齣四邊簡支層閤闆的固有頻率;將纖維鋪設角、跨厚比、彈性模量比對固有頻率的影響進行比較分析;基于高階剪切變形理論,用改進的適應度函數遺傳算法對複閤材料層閤闆的固有頻率進行優化設計。結果錶明:同經典薄闆理論和一階剪切變形理論相比,高階剪切變形理論更能精確地預報結構的固有頻率,優化後的層閤闆固有頻率明顯提高。
분별채용경전박판이론、일계전절변형이론급고계전절변형이론대복합재료층합판진행동태비선성분석。근거위이장도출층합판적허응변능、허동능급허공,유허위이원리득출층합판적공제방정。결합Navier삼각함수해구출사변간지층합판적고유빈솔;장섬유포설각、과후비、탄성모량비대고유빈솔적영향진행비교분석;기우고계전절변형이론,용개진적괄응도함수유전산법대복합재료층합판적고유빈솔진행우화설계。결과표명:동경전박판이론화일계전절변형이론상비,고계전절변형이론경능정학지예보결구적고유빈솔,우화후적층합판고유빈솔명현제고。
Dynamic nonlinear analysis has been made for composite laminated plates by using the classical plate theory, first-order shear deformation theory and higher-order shear deformation theory. According to the displacement field derived of laminates virtual strain energy, kinetic energy, and virtual work, governing equations of laminates are obtained by the principle of virtual displacement. Using Navier series, the natural frequency of a simply supported laminated plates is compared and analyzed for effect of fiber laying angle, length to thickness ratio, elastic modulus ratio on the natural frequencies. The optimal design is made for the natural frequency of laminated composite plates based on the higher-order shear deformation theory. The numerical results show that it is available to use genetic algorithm for optimal design of the composite laminates, and the natural frequency using higher-order shear deformation theory is more accurate than that of the classical plate theory and the first order shear deformation theory. The natural frequency of laminated structures is obviously increasing after optimal design.