The various technologies presented herein relate to fabrication and operation of a heat exchanger that is configured to extract heat from an underlying substrate. Heat can be extracted by way of an air gap formed between an impeller and a baseplate. By utilizing a pump to create an initial air gap that is further maintained by rotation of the impeller relative to the baseplate, a spring can be utilized that can apply a force of greater magnitude to the impeller than is used in a conventional approach, thus enabling the weight of the impeller to be negligible with respect to a width of the air gap, thereby conferring the desirable feature of orientation independence with respect to gravity with no performance degradation.

A sealed greasable swivel connector for underground use in directional drilling operations. The swivel connector has first and second swivel heads with pulling eyes. The first swivel head is pressfit into a tubular member and welded in place. The second swivel head is welded to a bolt in a bearing arrangement which is sealed with a bushing in the tubular member and allows for rotational movement between the first swivel head/tubular member and second swivel head/bolt. A zerk fitting is provided in first swivel head for flushing any drilling mud through the bushing that may find its way into the connector out of the tubular member.

A bearing bush configured to support a journal of a journal cross of a cardan shaft includes a cylindrical circumferential wall that radially delimits an interior for receiving rolling elements and the journal and includes a base axially delimiting the interior. The base has a central holder configured to receive a slip disk for contacting the journal. The base may include a conical portion extending from the cylindrical circumferential wall and a flat central portion, and the holder may be formed as a depression in the flat central portion. Also a journal bearing assembly including the bearing bush.

A component of a universal joint bearing includes at least one casing having a cylindrical wall and a base and at least one formation projecting from the base. The at least one formation is receivable in a clamp of a rotational processing machine to secure the component to the rotational processing machine during a rotational machining of a wall of the component. Also a method that includes clamping the component by the formation and machining inner and outer surfaces of the component without unclamping the component.

The motor with deceleration mechanism includes: a motor shaft (11), which is accommodated in a motor case (21) and in which an axial end portion (11a) is formed into a spherical shape; a worm, arranged on the motor shaft (11); a worm wheel, accommodated in a gear frame and engaging with the worm; a radial bearing (41), rotatably supporting the motor shaft (11); and a first thrust bearing (42), which is disposed inside the motor case (21), and in which a shaft facing surface (42s) facing the axial end portion (11a) of the motor shaft (11) and a counter shaft facing surface (42c) on the opposite side are respectively formed spherically; an average sliding radius between the first thrust bearing (42) and the motor case (21) is larger than an average sliding radius between the first thrust bearing (42) and the motor shaft (11).

The motor with deceleration mechanism includes: a motor shaft (11), which is accommodated in a motor case (21) and in which an axial end portion (11a) is formed into a spherical shape; a worm, arranged on the motor shaft (11); a worm wheel, accommodated in a gear frame and engaging with the worm; a radial bearing (41), rotatably supporting the motor shaft (11); and a first thrust bearing (42), which is disposed inside the motor case (21), and in which a shaft facing surface (42s) facing the axial end portion (11a) of the motor shaft (11) and a counter shaft facing surface (42c) on the opposite side are respectively formed spherically; an average sliding radius between the first thrust bearing (42) and the motor case (21) is larger than an average sliding radius between the first thrust bearing (42) and the motor shaft (11).

A rotary bearing, in particular a large open-centered ring bearing, having two concentric bearing races, of which one bearing race has a groove which is open toward the other bearing race, and the other bearing race has a lug ring that engages in the aforementioned groove. The lug ring can be supported against the groove in the axial and radial directions of the rotary bearing with a plurality of bearing assemblies that include at least two axial bearings mounted on opposite lug ring end faces, and at least one radial bearing that is mounted on an outer surface of the lug ring. The plurality of bearing assemblies have at least one sliding bearing and at least one rolling bearing situated between the lug ring and the groove.

A rotary bearing, in particular a large open-centered ring bearing, having two concentric bearing races, of which one bearing race has a groove which is open toward the other bearing race, and the other bearing race has a lug ring that engages in the aforementioned groove. The lug ring can be supported against the groove in the axial and radial directions of the rotary bearing with a plurality of bearing assemblies that include at least two axial bearings mounted on opposite lug ring end faces, and at least one radial bearing that is mounted on an outer surface of the lug ring. The plurality of bearing assemblies have at least one sliding bearing and at least one rolling bearing situated between the lug ring and the groove.

To provide a synthetic resin thrust plate having usable plane accuracy while eliminating correction of the plane shape thereof with a hot-plate press and a method for manufacturing the same. A synthetic resin thrust plate 1 is a hollow disc-shaped, synthetic resin thrust plate having a plurality of radial grooves 2 and 3 at equiangular intervals in terms of a disc central angle on both thrust faces 1a and 1b, respectively. The grooves 2 on one thrust face 1a and the grooves 3 on another thrust face 1b are the same in number. The grooves 2 on the one thrust face 1a and the grooves 3 on the other thrust face 1b are arranged so as not to overlap with each other in a circumferential direction. In particular, the grooves 2 on the one thrust face 1a and the grooves 3 on the other thrust face 1b are arranged in a staggered manner so as to have an angular deviation of of an angular interval between the grooves adjacent to each other on the same thrust face in terms of the disc central angle.

A bearing support includes at least one sliding bearing defined by the bearing support and/or at least one rolling-element bearing having an outer raceway defined by the bearing support. The bearing support is formed from a fiber-plastic composite and includes an integrally formed sliding surface of the sliding bearing and/or an integrally formed raceway for rolling elements of the rolling-element bearing, and the fiber-plastic composite includes a matrix into which spatially oriented sliding fibers, for example, PTFE fibers, are embedded in a region of the sliding surface of the sliding bearing and/or a region of the raceway of the rolling-element bearing.