In　this　study,　the　creep　properties　of　cylindrical　metal　rubber　(MR)　specimen　under　static　compression　at　elevated　temperatures　were　investigated　by　a　series　of　creep　experiments.　The　cylindrical　MR　specimen　has　a　good　symmetrical　property,　and　the　mechanical　properties　are　consistent　in　its　different　axial　section.　The　failure　determination　parameters　of　MR　under　the　coupling　of　thermal　and　mechanical　static　load　of　the　forming　direction　were　proposed　in　four　aspects:　the　overall　height,　the　average　stiffness,　the　energy　dissipation,　and　the　variation　of　the　loss　factor.　The　variation　patterns　of　the　properties　of　the　MR　specimens　were　investigated　with　a　static　load　at　different　temperatures　for　324　h.　The　analytical　equipment,　including　the　simultaneous　thermal　analyzer　(TGA/DSC),　X-ray　diffractometer　(XRD),　and　scanning　electron　microscope　(SEM),　were　used　for　material　characterization　and　failure　analysis.　Based　on　the　results,　it　is　found　that　there　are　significant　differences　in　the　MR　property　variations　subjected　to　creep　tests　at　different　elevated　temperatures.　The　results　indicated　that　an　appropriate　heat　treatment　for　MR　specimens　would　improve　the　creep　resistance　at　elevated　temperatures.　In　addition,　the　overall　height　and　energy　dissipation　of　the　MR　specimens　were　increased,　and　the　average　stiffness　and　the　loss　factor　were　decreased　under　the　creep　tests　at　200　degrees　C　and　250　degrees　C.　However,　under　the　creep　tests　at　25　degrees　C,　300　degrees　C,　350　degrees　C,　and　400　degrees　C,　the　overall　height,　the　energy　dissipation　and　the　loss　factor　were　decreased,　but　the　average　stiffness　was　increased.