Abstract: A sealing mechanism comprises a support member forming part of the semiconductor producing apparatus which has a vacuum chamber, a rotation shaft rotatably received in the support member, and at least three seal rings axially spaced apart from each other between the support member and the rotation shaft to form a first fluid chamber close to the atmosphere and a second fluid chamber close to the vacuum chamber. The first fluid chamber is vacuumized to have a first pressure, and the second fluid chamber is also vacuumized to have a second pressure which is lower than the first pressure. The first and second fluid chambers work together to enhance the sealing performance of the sealing mechanism.

Abstract: A buffer seal adapted for use in a seal assembly including at least a primary seal, the seal assembly being adapted to provide a fluid seal between two relatively moving machine elements, such as a piston or rod of a first machine element moving within a cylindrical bore of a second machine element. The buffer seal comprises a sealing element and a resiliently deformable biasing element. The material, shape, and/or volume of the biasing element are selected to provide a desired biasing force sufficient to maintain a surface of the sealing element in sealing contact with a surface of the first machine element and to simultaneously maintain another surface of the sealing element in sealing contact with a surface of the second machine element. In one embodiment, the buffer seal may be configured such that axial movement and tilting of the buffer seal within its associated gland are substantially eliminated.

Abstract: In a fuel injector having a plunger-and-barrel pumping assembly, a sealing member is mounted within an annulus of a plunger to prevent the dilution of pressurized fuel within the barrel of the tool. The sealing member includes a hollowed cavity which traps upward moving pressurized fuel and forces an extension or wiper of the sealing member upward and outward into sealing engagement with the inner surface or bore of the barrel.

Abstract: A seal for hydraulic assemblies operating at high temperatures having adaptations (19, 20, 49, 50) for low pressures sealing and configured to move across the gap to be sealed at higher pressures with an angled base on a slope (23, 44) or a cup shape (73, 74) nested into a groove (72). The seal at the point of the gap being an elastic, metallic material.

Abstract: A rotary shaft sealing system comprising a rotary lip seal and its associated retention gland, wherein the each of the seal and the gland are complimentary of the other within the environment of use. The system is particularly adapted for the sealing of a rotary shaft in an environment wherein the hydraulic pressure upon the fluid within the gland is at least 20 psi, or higher; and, such fluid pressure within the gland is further subject to variation or surges at the time of start-up and/or during operation/use of the rotary shaft. The retention gland geometry assists in the direction and application of hydraulic pressure against the seal so as to increase the radial contact force between the seal lip and the rotary shaft, thus, insuring more complete and effective sealing at this contact interface. The seal of this system is preferable pre-loaded so as to apply positive sealing pressure against the rotary shaft both prior to and during use.

Abstract: In a fuel injector having a plunger-and-barrel pumping assembly, a sealing member is mounted within an annulus of a plunger to prevent the dilution of pressurized fuel within the barrel of the tool. The sealing member includes a hollowed cavity which traps upward moving pressurized fuel and forces an extension or wiper of the sealing member upward and outward into sealing engagement with the inner surface or bore of the barrel.

Abstract: A sealing mechanism comprises a support member forming part of the semiconductor producing apparatus which has a vacuum chamber, a rotation shaft rotatably received in the support member, and at least three seal rings axially spaced apart from each other between the support member and the rotation shaft to form a first fluid chamber close to the atmosphere and a second fluid chamber close to the vacuum chamber. The first fluid chamber is vacuumized to have a first pressure, and the second fluid chamber is also vacuumized to have a second pressure which is lower than the first pressure. The first and second fluid chambers work together to enhance the sealing performance of the sealing mechanism.

Abstract: A sealing mechanism comprises a support member forming part of the semiconductor producing apparatus which has a vacuum chamber, a rotation shaft rotatably received in the support member, and at least three seal rings axially spaced apart from each other between the support member and the rotation shaft to form a first fluid chamber close to the atmosphere and a second fluid chamber close to the vacuum chamber. The first fluid chamber is vacuumized to have a first pressure, and the second fluid chamber is also vacuumized to have a second pressure which is lower than the first pressure. The first and second fluid chambers work together to enhance the sealing performance of the sealing mechanism.

Abstract: Fluid sealing system for installation within an assembly including a stationary machine part having a generally annular surface, and a reciprocable machine part having a generally cylindrical surface disposed concentrically with the annular surface of the stationary machine part. The system includes annular primary and secondary seal members each configured to be received within a corresponding gland of the annular surface coaxially intermediate the cylindrical surface of the movable machine part and a peripheral wall of the glands. The primary seal member has axially spaced-apart upper and lower end faces, and radially spaced-apart inner and outer diameter faces. The inner diameter face is formed to contact the cylindrical surface of the movable machine part along at least one dynamic sealing surface, and the outer diameter face is formed to contact the peripheral side wall of the gland along at least one static sealing surface.

Abstract: A sealing arrangement (6, 20, 37) to be positioned between two adjacent members (2, 3; 12, 13; 26, 27) between which a fluid cavity (4) is defined. Such a sealing arrangement is by example used in a swivel structure. If the exerted pressure is considerable two members will move from each other resulting in a larger spacing of the gap between them. During increasing of the pressure the requirements set to sealing do increase. According to the invention it is proposed to provide the members (2, 3; 12, 13; 20, 27) with L-shaped extensions and inverted L-shaped extensions (10, 11; 19, 21; 29, 30; 34, 35) which engage into each other and in between a spacing is defined for accommodating the sealing. If the pressure of the fluid in the cavity arises the spacing for the sealing will substantially decrease.

Abstract: Methods of sealing a planetary rotor engine, and the resulting seals, are described which improve the engine's efficiency and solves each of three main problem areas. A first method and resulting dynamic seal for sealing the rotor face surfaces as they translate across one another to constantly reform the contact between each other includes the key step of moving the shaft centerlines of each of the rotors, thereby radially positioning the rotors along diametric axes at positions which compensate for varying thermodynamic conditions (e.g. thermal expansion or contraction of rotor materials). A second method and resulting dynamic seal for effectively minimizing leakage between the end space formed between the rotor end and the case includes the key step of introducing a surface depression of any shape on one, or both, of the rotor end and opposing casing, thereby eliminating the need for a frictional seal and, in essence, forming a pressure wave plug.

Abstract: A slide disc seal for use in a roll of a paper or board making machine or finishing apparatus, which roll comprises a stationary axle (1) and a rotatable shell (2) with an end element (8) at each end and bearing elements (3) at each end of the roll. The slide disc seal comprises a circular sliding surface (10) on the end element (8), a chamber (18) on the other of the components (1) placed axially on the area of the sliding surface (10) and extending radially in relation to the sliding surface (10), and a ring-shaped sliding seal disc (15) having an inner edge, an outer edge and a lip seal (16) on one of the edges, the seal disc (15) being slidingly fitted within the chamber (18) so that the edge having the lip seal (16) is against the sliding surface (10) and the other edge of the seal disc (15) is within the chamber (18).

Abstract: A gas spring with a sealing and bearing assembly received within a casing of the gas spring adjacent to a rod slidably received through the assembly for axial reciprocation. The assembly has an annular retaining ring received within the casing, an annular bearing with a throughbore through which the rod reciprocates carried by the retaining ring, an annular retainer carried by the retaining ring downstream of the bearing, and a sealing member received within the retaining ring adjacent to the retainer and in firm engagement with the rod and retaining ring to provide a gas-tight seal between the rod and the retaining ring to prevent the escape of gas from the gas spring. The retainer preferably has a dovetail flange extending therefrom and the sealing ring has a complementarily shaped recess molded or press-fit onto the flange to attach the sealing ring to the retainer. The retainer is preferably firmly clamped to the retaining ring by rolling its upper edge over the retainer.

Abstract: A piston seal has formed on one side of the piston body upon which oil pressure works are a tapered surface portion which extends in a direction away from a piston sliding wall and a parallel surface portion. A lip-like seal is formed of a seal base portion which is, in cross section, approximately triangular to fill a space defined between the tapered surface portion and the piston sliding wall, and a lip portion which is formed integrally with the seal base portion. Q indicates the exertion line of a force which presses the lip portion against the piston sliding wall. T is a normal line which extends from the tapered surface portion towards the piston sliding wall. In order to prevent the lines Q and T from intersecting with each other within the bore, the seal base portion is arranged to lie apart from the lip portion in relation to the axial direction of the bore.