A system for elastically compensating for wear, thermal expansion and misalignment comprises a ring located between a housing and a pin in the bore of the housing. The ring has a backing layer, an expanded grid structure having a plurality of openings, a low friction layer penetrated into the openings of the expanded grid structure, and adhesive for bonding the backing layer, expanded grid structure and low friction layer together to provide elastic deformation of the ring between the housing and pin.

A gas pressure bearing element including a housing element with recesses, wherein the housing element is closed by a cover, wherein the recesses are defined by rib shaped intermediary walls and/or other island shaped protrusions and define first intermediary spaces between the intermediary walls and/or the island shaped protrusions, wherein the cover is formed in sections by a cured encasement compound provided with an open pore reinforcement mat, wherein the encasement compound has a flat surface that is processed after curing and forms a bearing surface for the gas pressure bearing element, wherein the bearing surface includes a plurality of gas outlet nozzles which are formed by micro holes penetrating the cover, and wherein the micro holes are provided at locations under which the first intermediary spaces are arranged below the cover, which first intermediary spaces form channels for a pressurized gas supply for the gas outlet nozzles.

A gas pressure bearing element including a housing element with recesses, wherein the housing element is closed by a cover, wherein the recesses are defined by rib shaped intermediary walls and/or other island shaped protrusions and define first intermediary spaces between the intermediary walls and/or the island shaped protrusions, wherein the cover is formed in sections by a cured encasement compound provided with an open pore reinforcement mat, wherein the encasement compound has a flat surface that is processed after curing and forms a bearing surface for the gas pressure bearing element, wherein the bearing surface includes a plurality of gas outlet nozzles which are formed by micro holes penetrating the cover, and wherein the micro holes are provided at locations under which the first intermediary spaces are arranged below the cover, which first intermediary spaces form channels for a pressurized gas supply for the gas outlet nozzles.

A system for elastically compensating for wear, thermal expansion and misalignment comprises a ring located between a housing and a pin in the bore of the housing. The ring has a backing layer, an expanded grid structure having a plurality of openings, a low friction layer penetrated into the openings of the expanded grid structure, and adhesive for bonding the backing layer, expanded grid structure and low friction layer together to provide elastic deformation of the ring between the housing and pin.

A system for elastically compensating for wear, thermal expansion and misalignment comprises a ring located between a housing and a pin in the bore of the housing. The ring has a backing layer, an expanded grid structure having a plurality of openings, a low friction layer penetrated into the openings of the expanded grid structure, and adhesive for bonding the backing layer, expanded grid structure and low friction layer together to provide elastic deformation of the ring between the housing and pin.

A connector for connecting first and second members includes a body formed of a composite material including reinforcing fibers embedded in a plastic matrix made of resin, and having a fastening zone for the first member and a housing. A ball joint is swivelable within the housing of the body and has a bore for the fastening of the second member. A first fibrous strip, or a coating, has a coefficient of friction less than or equal to 0.1 and is positioned between the housing and the ball joint in contact with the ball joint. A second fibrous strip having a coefficient of friction greater than or equal to 0.2 is positioned between the housing and the ball joint in contact with the housing.

A linear guide mechanism includes a housing having an inside housing surface that defines a bore extending through the housing coaxial with a longitudinal axis. A shaft is disposed at least partially in the bore and is reciprocatably and linearly moveable in the bore along the longitudinal axis. The shaft has an exterior shaft surface. A self-lubricating liner is disposed in the bore between the inside housing surface and the exterior shaft surface. The self-lubricating liner has an inside liner surface that is in sliding engagement with the exterior shaft surface of the shaft. The self-lubricating liner has an exterior liner surface.

A linear guide mechanism includes a housing having an inside housing surface that defines a bore extending through the housing coaxial with a longitudinal axis. A shaft is disposed at least partially in the bore and is reciprocatably and linearly moveable in the bore along the longitudinal axis. The shaft has an exterior shaft surface. A self-lubricating liner is disposed in the bore between the inside housing surface and the exterior shaft surface. The self-lubricating liner has an inside liner surface that is in sliding engagement with the exterior shaft surface of the shaft. The self-lubricating liner has an exterior liner surface.

Upset oilfield tubing or upset pump rods are protected from abrasive wear by non-metallic circumferential wear bands formed around and bonded to the upset portions of the tubing or rods and/or at selected locations along non-upset portions of the tubing or rods between the upset ends, such as by means of injection molding. The wear bands may be formed from a material comprising a thermoplastic polyurethane. The thermoplastic polyurethane may be a polyester-based thermoplastic polyurethane or a polyether-based thermoplastic polyurethane. The wear bands may incorporate stainless steel mesh or glass fibers or other reinforcing materials embedded in the thermoplastic polyurethane material.

Upset oilfield tubing or upset pump rods are protected from abrasive wear by non-metallic circumferential wear bands formed around and bonded to the upset portions of the tubing or rods and/or at selected locations along non-upset portions of the tubing or rods between the upset ends, such as by means of injection molding. The wear bands may be formed from a material comprising a thermoplastic polyurethane. The thermoplastic polyurethane may be a polyester-based thermoplastic polyurethane or a polyether-based thermoplastic polyurethane. The wear bands may incorporate stainless steel mesh or glass fibers or other reinforcing materials embedded in the thermoplastic polyurethane material.