The　entangled　metal　wire　material　based　on　multi-strand　twisted　wire　is　a　novel　porous　elastomeric　material,　which　has　attracted　much　attention　in　the　sandwich　structure　core　layer　material　due　to　its　superior　performance.　In　this　paper,　a　novel　ceramic/multi-strand　twisted　wire-based　entangled　materials　(MTWEM)　sandwich　structure　is　prepared,　whose　core　layer　is　divided　into　multi-strand　twisted　spiral　coil　(SC-MTWEM)　and　multi-strand　twisted　wire　mesh　(WM-MTWEM).　By　scanning　electron　microscopy　(SEM)　and　energy-dispersive　x-ray　spectroscopy　(EDS),　the　joint　surface　is　revealed　to　be　flawless,　and　the　elemental　distribution　and　compound　composition　of　the　joint　are　analyzed.　The　interface　strength　of　the　sandwich　structure　is　examined　by　tensile　tests,　and　the　forms　of　damage　are　investigated　under　the　macroscopic　and　microscopic　aspects.　The　effects　of　three　factors,　namely　the　MTWEM　density,　MTWEM　thickness,　and　ceramic　panel　thickness,　on　the　bending　resistance　are　investigated　by　a　three-point　bending　test.　The　test　results　indicate　that　the　damage　is　dominated　by　the　fracture　of　the　ceramic　panel　and　the　shear　deformation　of　MTWEM.　The　evolution　of　the　damage　form　is　verified　by　simulation　analysis.　Bending　strength　and　energy　absorption　are　positively　correlated　with　MTWEM　density　and　ceramic　thickness,　and　the　fracture　of　the　ceramic　panel　is　delayed.　The　MTWEM　thickness　has　the　opposite　effect.　The　particular　cell　grid　of　WM-MTWEM　is　interlocked　and　interwoven　with　each　other.　It　allows　the　bending　strength　and　energy　absorption　to　be　superior　to　that　of　SC-MTWEM　for　the　same　parameters,　but　the　timing　of　ceramic　panel　breakage　is　advanced.　©　2025　The　American　Ceramic　Society.