The　dynamic　tensile　tests　of　the　steel　grid-polyethylene　(PE)　fiber　reinforced　engineered　cementitious　composites　(ECC)　were　carried　out　at　low　and　medium　loading　rates.The　failure　state　and　characteristic　of　tensile　strength　and　energy　dissipation　of　the　steel　grid-PE　fiber　reinforced　ECC　were　investigated.　The　effects　of　fiber　volume　content,　number　of　steel　grid　layers　and　tensile　rate　on　the　dynamic　tensile　behaviors　of　the　steel　grid-PE　fiber　reinforced　ECC　were　also　investigated.　It　is　indicated　by　the　test　results　that:　the　ultimate　tensile　strength,　ductility　and　energy　dissipation　performance　of　the　ECC　are　improved　by　the　addition　of　steel　grids　and　PE　fibers.　Compared　to　the　matrix　material,　the　steel　grid-PE　fiber　reinforced　ECC　shows　remarkable　improvement　phenomena　of　ultimate　tensile　strength　and　energy　dissipation.　The　steel　grid　mostly　enhances　the　ultimate　tensile　strength　of　the　ECC,　and　the　PE　fiber　mostly　improves　the　ductility　and　energy　dissipation　performance　of　the　ECC.　The　fiber　volume　content,　number　of　steel　grid　layers　and　tensile　rate　all　impact　the　dynamic　tensile　behaviors　of　the　steel　grid-PE　fiber　reinforced　ECC　to　a　certain　extent.　The　ultimate　tensile　strength　and　energy　dissipation　performance　of　the　reinforced　ECC　can　be　enhanced　with　the　increase　of　fiber　volume　content.　For　the　tensile　rate　of　1mm/min,　an　increase　of　about　17%　is　recorded　for　the　peak　stress　of　the　reinforced　ECC　with　a　fiber　volume　content　of　0.5%　compared　to　the　matrix　material.　The　ultimate　tensile　strength　of　the　reinforced　ECC　reveals　remarkable　enhancement　with　the　increase　of　the　number　of　steel　grid　layers.　The　peak　stress　of　the　reinforced　ECC　with　one　layer　or　two　layers　of　steel　grid　increases　by　about　65%　and　192%　compared　to　the　matrix　material,　respectively.　But　the　deformation　capability　of　the　reinforced　ECC　shows　deterioration　with　the　increase　of　the　number　of　steel　grid　layers.　The　ultimate　tensile　strength　of　the　reinforced　ECC　can　be　enhanced　with　the　increase　of　tensile　rate.　The　reinforced　ECC　reveals　obvious　strain　hardening　behavior　and　has　considerable　ductility　and　energy　dissipation　performance　at　medium　tensile　rates.　©　2022,　Materials　Review　Magazine.　All　right　reserved.