FN Archimer Export Format PT J TI Optimal laminations of thin underwater composite cylindrical vessels BT AF MESSAGER, Tanguy PYRZ, Mariusz GINESTE, Bernard CHAUCHOT, Pierre AS 1:;2:;3:;4:; FF 1:;2:;3:;4:PDG-TMSI-RED-MS; C1 Ecole Cent Nanates, UPRESEA 2166, Lab Mecan & Mat, F-44321 Nantes 3, France. CNRS, URA 1441, Lab Mecan Lille, F-59655 Villeneuve Dascq, France. Univ Bretagne Occidentale, EA 940, Lab Rheol & Mecan Struct, F-29285 Brest, France. IFREMER, Serv Mat & Struct, F-29280 Plouzane, France. C2 ECOLE CENT NANATES, FRANCE CNRS, FRANCE UNIV BRETAGNE OCCIDENTALE, FRANCE IFREMER, FRANCE SI UBO BREST SE PDG-TMSI-RED-MS IN WOS Ifremer jusqu'en 2018 copubli-univ-france IF 0.786 TC 90 UR https://archimer.ifremer.fr/doc/2002/publication-759.pdf LA English DT Article DE ;Experimental results;Optimal design;Buckling;Lamination;Cylinder;Composite AB This paper deals with the optimal design of deep submarine exploration housings and autonomous underwater vehicles. The structures under investigation are thin-walled laminated composite unstiffened vessels. Structural buckling failure due to the high external hydrostatic pressure is the dominant risk factor at exploitation conditions. The search of fiber orientations of the composite cylinders that maximize the stability limits is investigated. A genetic algorithm procedure coupled with an analytical model of shell buckling has been developed to determine numerically optimized stacking sequences. Characteristic lamination patterns have been obtained. FEM analyses have confirmed the corresponding significant increases of buckling pressures with respect to initial design solutions. Experiments on thin glass/epoxy and carbon/epoxy cylinders have been performed. The measured buckling pressures appear to be in good agreement with numerical results and demonstrate the gains due to the optimized laminations. PY 2002 PD DEC SO Composite Structures SN 0263-8223 PU Elsevier VL 58 IS 4 UT 000179253300013 BP 529 EP 537 DI 10.1016/S0263-8223(02)00162-9 ID 759 ER EF