In　this　paper,　the　dynamic　model　of　an　eccentric　rotating　carbon　fiber　reinforced　polymer　(CFRP)　laminated　cylindrical　shell　based　on　the　first-order　shear　deformation　theory　is　established　for　the　first　time.　The　buckling　and　free　vibration　analyses　of　the　eccentric　rotating　CFRP　laminated　cylindrical　shell　under　the　axial　excitation　are　presented.　Taking　into　account　the　influences　of　Coriolis　force　and　centrifugal　force　caused　by　eccentric　rotation.　By　utilizing　the　Hamilton　principle,　the　first-order　shear　deformation　theory　and　the　von-Karman　type　nonlinear　geometric　relationship,　a　system　of　the　partial　differential　governing　equations　for　the　eccentric　rotating　CFRP　laminated　cylindrical　shell　is　derived.　Then,　the　ordinary　differential　equations　of　the　eccentric　rotating　CFRP　laminated　cylindrical　shell　are　obtained　according　to　Galerkin　method.　The　present　method　are　validated　by　carrying　out　some　comparisons　with　the　existing　results　in　the　published　literatures.　The　natural　frequencies　and　critical　buckling　loads　of　the　system　are　solved　numerically.　In　this　study,　the　influences　of　the　eccentric　distance,　ratio　of　radius　to　length,　rotating　speed　as　well　as　the　number　of　layers　of　the　eccentric　rotating　CFRP　laminated　cylindrical　shell　on　the　buckling　and　free　vibration　behaviors　are　discussed.&　nbsp;　(c)　2021　Elsevier　Inc.　All　rights　reserved.