Patent ID: 7967281
Filing Date: 2011-06-28
Classification: F16F

Abstract:
1. A method of isolating a body and a structure comprising: providing a structure having a surface; providing a body located away from the structure, said body having a body fastener location for isolation fastening to said body; providing a resilient member iso-elastic vibration isolation member with an outer member with a planar base and a conical shroud and with an inner member with an axially extending stem, said vibration axially extending stem fastened to said body at said body fastener location to provide a resilient connection between said outer member conical shroud and said body fastener location to reduce the transmission of vibratory disturbances between the body and said structure and to provide an isolation of said body from said structure, the vibration isolation member inner member including a frustoconical seat having an angled surface and an outer periphery diameter D′; said outer member including a planar base with said conical shroud extending away from the planar base, the conical shroud extending to overlay the inner member outer periphery diameter D′, said conical shroud having an angled segment with an inner surface, said angled segment inner surface oriented substantially parallel to said angled surface of said frustoconical seat, said angled segment inner surface and said substantially parallel angled surface of said frustoconical seat angled relative to a radial direction axis and a perpendicular axial direction axis extending in a direction along said axially extending stem with said perpendicular axial direction axis perpendicular to said radial direction axis wherein extensions of said angled segment inner surface and said substantially parallel angled surface of said frustoconical seat intersect both said radial direction axis and said axial direction axis with said conical shroud defining an inner periphery diameter D″ with said axially extending stem extending out through said inner periphery diameter D″ along said perpendicular axial direction axis outward towards said body fastener location with said stem fastened to said body, said inner periphery diameter D″ less than said outer periphery diameter D′, said outer member planar base joined to said structure surface with said outer member conical shroud and said structure surface comprising a chamber with the inner member seat contained within said chamber; and said resilient connection between said outer member conical shroud and said body fastener location consisting essentially of a single resilient member constrained between the conical shroud angled segment inner surface and the inner member frustoconical seat angled surface, said single resilient member having a cross section, said single resilient member cross section bonded to said shroud angled segment inner surface and said inner member frustoconical seat angled surface with said single resilient member cross section contained within said chamber and between said shroud angled segment inner surface and said inner member frustoconical seat angled surface, wherein said contained within single resilient member cross section bonded to said conical shroud angled segment inner surface and said inner member frustoconical seat angled surface provides for iso-elastic displacement of said inner member in a radial direction along said radial direction axis and in an axial direction along said axial direction axis from said outer member with said frustoconical seat outer periphery diameter D′ providing an interference with said conical shroud inner periphery diameter D″ to prevent a separation of the vibration isolation member in the event of a failure of said resilient connection consisting essentially of said single resilient member cross section contained within said chamber, wherein said single resilient member cross section isolates said body and said structure with said iso-elastic vibration isolation member providing a substantially equal dynamic stiffness in the radial direction along said radial direction axis and in the axial direction along said axial direction axis for an applied load between the body and the structure.