A sealing device includes a metal ring, a main lip, an annular elastic body, a sliding ring, and biasing means. The metal ring is hermetically fixed to a housing. The main lip is bonded to the metal ring and is slidably in close contact with an outer periphery surface of a rotating body inserted through an inner circumference of the housing. The annular elastic body is bonded to the metal ring on an outer side of the main lip, and stretchable in an axial direction. The sliding ring is provided at an end portion of the annular elastic body on a side opposite the metal ring, and is slidably in close contact with a seal flange attached to an outer periphery of the rotating body. The biasing means is configured to elastically press the sliding ring against the seal flange, thereby maintaining stable sealability over an extended period of time.

In some embodiments, apparatuses are provided herein useful to sealing a gap, such as a gap between a gas turbine engine nozzle flap and sidewall. An apparatus for sealing such a gap may be a plunger seal that includes a plunger, a retaining element, a guide pin, and a biasing element. The plunger includes a sealing edge and an actuating edge having at least one recess and an opening formed therein. The biasing element and a portion of the guide pin are nested in the recess. The retaining element anchor the plunger to the retaining element. The retaining element also anchors the plunger seal to the housing When installed in a gap, the housing engages the flap and the plunger engages the sidewall. The biasing element is under compression and urges the guide pin into the actuating edge to urge the plunger toward the sidewall and seal the gap.

Systems and assemblies are provided for sealing an interface between a cylinder and a manifold corresponding to the cylinder. The cylinder comprises at least one port. A manifold interface is arranged adjacent to the at least one port. A seal is located inside of a circumferential pocket, wherein the circumferential pocket comprises at least a portion of the manifold interface. A spring is configured to preload the seal radially inward so that the seal stays in contact with the outer surface of the cylinder.

A mechanical seal includes a drive ring having an axially extending drive element and a seal face with an outer substantially cylindrical surface that is provided with a corresponding radially reduced portion that is can be engaged by the drive element, in which the radially reduced portion is a flat surface that is, in transverse section a chord, and the drive element is provided with a flat surface that can engage with the flat surface of the radially reduced portion during driving rotation of the seal face by the drive ring.

A sealing element assembly (1) for a single type mechanical shaft seal assembly (2) is adapted to be arranged between the circumference of a rotatable shaft (3) and a static housing (4) surrounding the shaft (3). A first side (5) in an axial direction of the sealing element assembly (1) is adapted to face an enclosed space (6) between the housing (4) and the shaft (3) and the opposite second side (7) of the sealing element assembly (1) is adapted to face an ambient space (8), wherein the sealing element assembly (1) is adapted to be at least partly moveably arranged in an axial direction from a non-sealing position to a sealing position. The sealing element assembly (1) in the non-sealing position is adapted to be arranged at distance from a surface (10) of a plane that is transversal or tapered up to ?5 degrees to an axis of the shaft (3). The sealing position of the sealing element assembly (1) is arranged to seal against said surface (10) such that the sealing element assembly (1) constitutes a sealing between the rotatable shaft (3) and the housing (4) when the enclosed space (6) is pressurized.

A fluid end assembly comprising a plurality of fluid end sections positioned in a side-by-side relationship. Each section comprises a housing containing a reciprocating plunger. One and only one packing seal is installed within the housing and surrounds and engages an outer surface of the plunger. A retainer compresses and holds the packing seal within the housing. The retainer is secured to the housing using a clamp, such that no threads are formed in the housing of the fluid end section and no threads are formed in the retainer.

A two-position handpiece coupling seal is provided. The two-position handpiece coupling seal includes a neck disposed at a first end that is configured to receive an implement. The two-position handpiece coupling seal has a first seal disposed about the neck of the two-position handpiece coupling seal. The first seal is configured to engage with a surface of a housing of a handpiece that uses the two-position coupling seal in a first position. The two-position handpiece coupling seal has a second seal disposed about a bore of the two-position handpiece coupling seal at a second end of the two-position handpiece coupling seal opposite the first end. The bore is configured to receive a driveshaft and the second seal is configured to sealingly engage with the driveshaft when the bore receives the driveshaft.

An end surface-contact mechanical seal providing a shielding seal between a liquid area (A) and an atmospheric area (B) by a relative rotation, while in a contact state, of opposing end surfaces (4a, 6a) of a case-side sealing ring (4), which is fixed to a seal case, and a ceramic shaft-side sealing ring (6), which is held on the sleeve (22) of a rotary shaft (2). A rubber O-ring (5) is installed between a sealing ring-side seal surface (63a), which is formed on the inner peripheral surface of the shaft-side sealing ring (6), and a shaft-side seal surface (22c), which is formed on the outer peripheral surface of the sleeve (22), so as to be relatively movable in the axial direction while sealing the surfaces. A diamond film (14a) is formed over the entire surface of the sealing ring-side seal surface (63a).

An annular sealing device in a recess in a housing has a movable annular piston; and an annular inner periphery sealing lip adhered to part of a first edge along an inner periphery of the piston and that slides while in contact with the recess. The first edge has a first inner periphery edge with a first thickness; a second inner periphery edge adjoining the first inner periphery edge and with a thinner second thickness; and a third inner periphery edge adjoining the second inner periphery edge and with a thinner yet third thickness. The first, second, and third inner periphery edges are in this order from the outer periphery of the piston. The inner periphery sealing lip is adhered to the third inner periphery edge and part of the second inner periphery edge to cover a step formed by thickness differences between the second and third inner periphery edges.

The shaft seal arrangement for a rotating turbomachine shaft having a rotation axis, comprises a rotor part and a stationary part. A dry gas seal is further provided, in combination with a cooling fluid volume arranged for receiving a cooling fluid and in heat exchange relationship with the dry gas seal. A venting arrangement collectively vents exhaust cooling fluid and dry sealing gas from the shaft seal arrangement.