An apparatus for use in installing and verifying installation of a seal member in a component, and including a housing defining an interior sized to receive the component therein, and a moveable lid selectively positionable between a loading position and a sensing position. The apparatus also includes at least one seal sensor coupled to the moveable lid and configured to selectively align with a first sensing point on the component when the moveable lid is in the sensing position. The at least one seal sensor is configured to only actuate when pressed against the seal member positioned at the first sensing point.

In a state where a pair of protrusion portions of a ring portion is clamped by front end engagement portions of a pair of claw members (71) (72), the front end engagement portions of the pair of claw members are swung in a direction approaching each other about a pivotal supporting portion (80). A sliding body (77) slides with the contact of the front end engagement portion to the ring portion or to the protrusion portion thereof so as to follow a radial and circumferential displacement of the protrusion portion accompanying a diameter reduction of the ring portion.

A boot band for fixing a boot that is mounted to a constant velocity universal joint is clamped. The boot band and the constant velocity universal joint are aligned in phase with each other in a circumferential direction. An axial position of a clamping portion is thereafter aligned with an axial position of the boot band. Then, the boot band is clamped by the clamping portion.

A differential gear set assembling method includes: a pivoting step of closing openings by guide portion and pivoting a pair of pinions between a pair of side gears; and an insertion step of inserting a pinion shaft into a pair of case shaft holes and a pair of pinion shaft holes from outside the differential case. The pivoting step is performed in a state where projecting portions are buried in the guide portions. The insertion step is performed in a state where the projecting portions are projected from the guide portions toward the pair of side gears, and the pair of side gears are pressed by the projecting portions so as to apply loads against biasing forces of coned disc springs to the pair of side gears.

A method of mounting an elastic ring, e.g., sealing ring, on a body via a mounting unit is presented, having at least three fingers which are movable relative to each other. The method comprises holding and clamping the ring on the exterior side of the fingers which extend into a cross-section framed by the ring, moving at least one finger along a circle or a plurality of fingers along a common circle or a plurality of concentric circles such that the elastic ring is stretched and the cross-section thereof is increased, moving the ring and the component relative to each other so that the component projects into the cross-section and the ring extends around the component, moving one or more fingers relative to each other so that the ring contacts the component in sections between adjacent fingers, and moving the fingers out of the ring. Also disclosed are a mounting unit for executing the method, and a ring mounting device including such a mounting unit.

The present invention relates to a retained member configured to prevent centrifugal force from disassociating a retaining ring provided with lugs from a groove located on a rotatable shaft when securing the retained member to the rotatable shaft and rotating with the shaft. The retained member includes a substantially annular portion and a retention lip provided with a cutout portion. The substantially annular portion defines an opening sized to receive the rotatable shaft so that the retained member is rotatable with the shaft. The cutout portion is configured to accommodate the lugs when in an installing position as the retained member is snap fit into the groove.

One aspect of the invention provides a method of forming an energy-dissipative tube. In one embodiment, the method includes: extruding a resin layer over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles. In another embodiment, the method includes: extruding a resin layer comprising a fire retardant over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles. In another embodiment, the method includes: extruding a resin layer comprising between about 20% to 60% magnesium hydroxide, aluminum trihydrate, or halogenated fire retardants by weight over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles selected from the group consisting of: copper, aluminum, gold, silver, and nickel.

One aspect of the invention provides a method of forming an energy-dissipative tube. In one embodiment, the method includes: extruding a resin layer over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles. In another embodiment, the method includes: extruding a resin layer comprising a fire retardant over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles. In another embodiment, the method includes: extruding a resin layer comprising between about 20% to 60% magnesium hydroxide, aluminum trihydrate, or halogenated fire retardants by weight over an outer surface of corrugated stainless steel tubing and impregnating the resin layer with metal particles selected from the group consisting of: copper, aluminum, gold, silver, and nickel.

The present disclosure provides radial springs that control radial forces between adjacent concentric components. The radial springs may be configured for placement between the adjacent concentric components. The radial springs may include a base member, support members extending from the base member, and resilient members extending from the base members. The resilient members may extend radially, axially, at an angle relative to the axis, or a combination thereof, and may be radially deformable. The resilient members may exert radial forces substantially uniformly radially inward or outward in use. The resilient members may be leaf type members or cantilever type members. The support members and resilient members may be provided on a radially inward or outward side of the base member. The methods of installing and uninstalling radial springs may include engaging the resilient members with a tool and radially deforming the resilient members to engage or disengage the radial spring from an adjacent concentric component.

A piston ring installation jig is to be used when installing a piston ring having a ring gap in a ring groove formed in an outer peripheral surface of a piston. The piston ring installation jig includes a main body including a groove. The main body has in a semi-cylindrical shape surrounding the outer peripheral surface of the piston. The groove has a substantially semicircular arc shape, and is formed in an inner peripheral surface of the main body in a region corresponding to the ring groove of the piston. A portion of the piston ring in a circumferential direction is inserted into the groove. The groove has a shape of an arc of a circle which has a circle center biased more to an outer peripheral side of the main body than a circle center of an inner peripheral surface of the main body.