The　entangled　metal　wire/silicone　rubber　continuous　interpenetrated　phase　composite　(EMW-SRC)　is　a　highperformance　damping　material　with　silicone　rubber　as　matrix　and　metal　wire　turns　as　the　reinforcement　skeleton.　EMW-SRC　has　good　damping　characteristics　and　significant　load-bearing　stiffness.　This　work　first　characterizes　the　fine　interface　morphology　and　macroscopic　mechanical　characteristics　of　the　EMW-SRC　and　adopts　a　computer-aided　preparation　technology　to　accurately　reconstruct　the　complex　structure　of　the　spatially　random　distribution　of　the　entangled　metal　wire　material.　It　develops　a　finite　element　model　of　the　EMW-SRC　with　highquality　structured　mesh　based　on　the　domain　mesh　superposition　method　cohesive　cells　to　share　and　embed　the　surface　nodes　at　the　interface.　Moreover,　the　composite　interface　bonding　performance　between　metal　wire　and　silicone　rubber　is　investigated,　the　interfacial　bonding　parameters　are　determined,　and　the　reliability　of　the　mesh　model　is　assessed　by　comparing　the　results　of　a　single　wire　pull-out　test　and　simulation　analysis.　Based　on　this,　quasi-static　compression　test　and　simulation　of　the　material　are　further　performed,　with　the　simulation　results　matching　well　with　the　experimental　ones.　The　mesoscale　simulation　results　show　that　the　metal　wire　inside　the　EMW-SRC　can　overcome　the　silicone　rubber　restriction　on　micro-slip　during　the　load-bearing　process.　The　metal　wire　micro-element　is　subjected　to　torsional　load.　Under　a　compression　displacement　of　0.7　mm,　the　composite　interface　bonding　remains　intact　without　damage.　In　conclusion,　the　developed　model　can　provide　a　prior　guidance　on　the　preparation　and　use　conditions　of　the　proposed　material　and　offers　an　effective　way　to　investigate　the　fine-mechanics　of　such　materials　with　high　damping　and　high　load-bearing　characteristics.