DYNAMIC STABILITY OF A COMPOSITE CIRCULAR CYLINDRICAL-SHELL SUBJECTEDTO COMBINED AXIAL AND TORSIONAL LOADING

The dynamic stability of thin, clamped, composite circular cylindrical shells is studied for combined axial and torsional loading. Each load is taken to be harmonically varying; the frequencies of the two loads differ, in general. For the case in which the frequencies are commens urate, the applied load function is periodic. The equations of motion for the shell are reduced to a system of Hill equations by means of Fo urier series expansions. Instability regions of principal and combinat ion parametric resonance are determined by use of the monodromy matrix . Numerical results are generated for boron-epoxy layered shells for v arious cases of pure axial, pure torsional, and combined loading. The width of the principal instability region is presented as a function o f fiber orientation for a laminate case. Stability diagrams are presen ted covering about 6 times the lowest natural frequency for various ra tios of the applied axial and torsional frequencies.