The　primary　barrier　to　the　widespread　use　of　super-wetting　materials　is　the　surface＇s　limited　resistance　to　physical　damage,　which　leads　to　poor　mechanical　qualities.　In　this　study,　framework-reinforced　orderly-woven　superhydrophobic　metal　spiral　coil-carbon　fibers　composites　(SMSC-CFsC)　with　a　durable　uniform　microstructure　were　prepared　by　nested　carbon　fibers　into　metal　spiral　coils　cleverly　and　woven　them　into　a　threedimensional　porous　material　innovatively.　The　separation　purity　of　the　prepared　metal-carbon　composites　on　several　commonly　used　industrial　lubricating　oil　emulsions　was　better　than　99.90　%　and　the　flux　was　greater　than　1000　L/m2h.　More　significantly,　computational　fluid　dynamics　was　used　to　establish　a　simulation　model　for　emulsion　separation　that　revealed　the　real-time　dynamic　motion　trajectory　and　volume　changes　of　water　droplets.　Additionally,　even　after　high-temperature,　compression,　wear,　and　corrosion　experiments,　it　still　showed　dependable　separation　purity　and　stable　flux.　As　a　result,　it　has　been　demonstrated　that　the　proposed　metal-carbon　composite　has　a　long　oil-water　separation　service　life　in　harsh　environments　and　has　great　potential　for　developing　efficient　and　durable　emulsion　separation　materials.