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Vinson JR. Sandwich structures. Applied Mechanics Reviews. 2001;54(3):201–214.Search in Google Scholar
Icardi U. Applications of Zig-Zag theories to sandwich beams. Mechanics of Advanced Materials and Structures. 2003;10(1):77–97.Search in Google Scholar
Yang M, Qiao P. Higher-order impact modeling of sandwich structures with flexible core. International Journal of Solids and Structures. 2005;42(20):5460–90.Search in Google Scholar
Magnucka-Blandzi E, Magnucki K. Effective design of a sandwich beam with a metal foam core. Thin-Walled Structures. 2007;45(4):432-8.Search in Google Scholar
Kreja I. A literature review on computational models for laminated composite and sandwich panels. Central European Journal of Engineering. 2011;1(1):59-80.Search in Google Scholar
Wang ZD, Li ZF. Theoretical analysis of the deformation of SMP sandwich beam in flexure. Archive of Applied Mechanics. 2011;81(11):1667–78.Search in Google Scholar
Nguyen CH, Chandrashekhara K, Birman V. Enhanced static response of sandwich panel with honeycomb cores through the use of stepped facings. Journal of Sandwich Structures and Materials. 2011;13(2):237-60.Search in Google Scholar
Phan CN, Frostig Y, Kardomateas GA. Analysis of sandwich beams with a compliant core and with in-plane rigidity–extended high-order sandwich panel theory versus elasticity. ASME: Journal of Applied Mechanics. 2012;79:041001–1-11.Search in Google Scholar
Magnucki K, Jasion P, Szyc W, Smyczynski M. Strength and buckling of a sandwich beam with thin binding layers between faces and a metal foam core. Steel and Composite Structures. 2014;16(3):325-37.Search in Google Scholar
Sayyad AS, Ghugal YM. Bending, buckling and free vibration of laminated composite and sandwich beams: a critical review of literature. Composite Structures. 2017;171:486–504.Search in Google Scholar
Birman V, Kardomateas GA. Review of current trends in research and applications of sandwich structures. Composites Part B. 2018;142:221-40.Search in Google Scholar
Kozak J. Steel sandwich panels in ship structures. Gdańsk Tech Publishing House, 2018, Gdańsk. ISBN 978-83-7348-742-0 (in polish).Search in Google Scholar
Magnucki K. Bending of symmetrically sandwich beams and I-beams – Analytical study. International Journal of Mechanical Sciences. 2019;150:411-9.Search in Google Scholar
Magnucki K, Magnucka-Blandzi E, Lewiński J, Milecki S. Analytical and numerical studies of an unsymmetrical sandwich beam - bending, buckling and free vibration. Engineering Transactions. 2019;67(4):491-512.Search in Google Scholar
Sayyad AS, Ghugal YM. Modeling and analysis of functionally graded sandwich beams: A review. Mechanics of Advanced Materials and Structures. 2019;26(21):1776-95.Search in Google Scholar
Chinh TH, Tu TM, Duc DM, Hung TQ. Static flexural analysis of sandwich beam with functionally graded face sheets and porous core via point interpolation meshfree method based on polynomial basic function. Archive of Applied Mechanics. 2021;91(3):933–47.Search in Google Scholar
Magnucki K, Magnucka-Blandzi E, Wittenbeck L. Three models of a sandwich beam: Bending, buckling and free vibration. Engineering Transactions. 2022;70(2):97-122.Search in Google Scholar
Kustosz J, Magnucki K, Goliwąs D. Bending of a stepped sandwich beam: The shear effect. Engineering Transactions. 2022;70(4):373-390.Search in Google Scholar
