Provided is a nozzle structure, a blow device, and a manufacturing method for parts, a bearing, a linear motion device, a steering device, a vehicle, and a mechanical device which can uniformly and satisfactorily perform various processes with fluid over a wide range on a processing target member. The nozzle structure includes an inner member, an outer member surrounding the inner member, and a laminar flow path formed between an outer surface of the inner member and an inner surface of the outer member to allow fluid to flow. The blow device or the mechanical device having the nozzle structure can process the inner member by flowing the fluid in the flow path.

A substrate processing device includes shafts, rollers, a gas blowing unit, bearings, and s suction unit. The shafts include internal spaces and first through holes communicated with the internal spaces. The rollers are attached to the shafts to be rotatable about axes of the shafts for conveying a substrate. The gas blowing unit is configured to blow gas to the substrate carried by the rollers. The bearings support the shafts to be rotatable and include second through holes communicated with the first through holes of the shafts. The bearings include inner rings fitted on the shafts, outer rings opposed to outer peripheries of the inner rings, respectively, and rolling components disposed between the inner rings and the outer rings. The suction unit is configured to suck air in the internal spaces of the shafts.

The invention relates to a method for producing a multi-layer plain bearing element with a first layer made from a metal having an inner face, whereby this inner face is cleaned by scanning the entire inner face by means of a laser and at least one other layer is then applied to the inner face of the first layer. The cleaning is carried out using an ultrashort pulse laser.

To provide a retainer for a thrust bearing, which is to be assembled and decomposed regularly for being washed, having superior ball retaining performance itself and being attached and detached easily, and a thrust bearing having the retainer. A retainer for a thrust bearing 1, which retains a plurality balls intervened between a pair of raceway rings in a thrust bearing, is formed of a ring shaped plate member 2 formed of an injection molded body of a resin composition containing fluororesin, which is capable of injection molding, as a base resin. The ring shaped plate member 2 includes a plurality of ball pockets 3 in a circumferential direction of a ring shape. Each of the ball pockets 3 includes a claw portion divided into two portions 3a or more to retain a ball 5 in a detachable manner. The claw portion 3a is defined by a slit 4 formed on at least one surface 2a among facing surfaces of the ring shaped plate member 2 facing raceway rings, the slit 4 being formed around an opening 3d of the ball pocket 3.

A simple but effective manually operated bearing cleaning apparatus comprises a container adapted to receive a solvent. One or more brushes mounted on the inner sidewall of the container have bristles oriented generally toward a centerline of the container, while leaving a central opening enabling a bearing to pass therethrough. A telescoping sleeve including a lower sleeve with a lower end, and an upper sleeve with an upper end is configured to receive a bearing to be cleaned between upper and lower retainers on the upper sleeve. A coupling is provided between the lower end of the lower sleeve and the inner bottom surface of the container, whereby a user moves the upper sleeve in an up-and-down motion, forcing the bearing through the central opening of the bristles, thereby cleaning the bearing in the solvent.

A method for prolonging the service life of a product that is subjected to Hertzian contact stress when in use, and which includes a metal surface having at least one indentation, includes removing a first portion of the at least one indentation from the metal surface to provide a remanufactured product having a remanufactured metal surface having a second portion of the at least one indentation, obtaining information about the second portions of the at least one indentation, using the information to estimate potential stress concentrations that are detrimental to lubrication conditions and/or fatigue life of the remanufactured metal surface using analytical modelling, and providing a prediction of the performance of the remanufactured product based on the estimation.

A rotation mechanism includes: a housing; a shaft inserted through a hole provided at the housing; bearings installed at the housing and rotatably supporting the shaft; a rotary member provided at one end portion of the shaft, adapted to be rotated together with the shaft, and having a portion that projects to a radially outer side of the hole and faces the housing with a gap having a predetermined size; and a gas passage adapted to connect the gap to outside of the housing and allow gas contained in a portion of the gap to pass to the outside of the housing.

Various embodiments of stand-off devices and methods are disclosed. The stand-off device can space a bearing assembly apart from a support, such as a frame of a conveyor belt, thereby providing access between the bearing assembly and the frame, such as for cleaning fluid. Certain embodiments of the stand-off device include a first end and a second end, with the first end being receivable in a securing hole of the bearing assembly and the second end configured to protrude from the bearing assembly.

The casing (10) of a support assembly for food applications has a housing portion (20) having a through-seat (25) within which a bearing unit is seated. The casing has a flange portion (30) for fixing the casing to a machine. The flange portion has a base surface (35) and at least two through-holes (32) for housing elements for fixing the casing to the machine. The casing has at least two metal bushings (40), equal in number to the number of through-holes, housed stably inside respective through-holes and coaxial with them. The casing has at least two spacers (50), equal in number to the number of through-holes, applied on the base surface of the flange portion opposite the respective through-holes. The casing has at least two inserts (60), equal in number to the number of spacers, and housed with interference inside the respective metal bushings and inside the respective spacers.

A casing (10) of a support assembly for food applications has a housing portion (20) having a through-seat (25) inside which a bearing unit is seated. The casing has a flange portion (30) for fixing the casing to a machine. The flange portion has a base surface (35) and at least two through-holes (32) for housing elements for fixing the casing to the machine. The casing has at least two metal bushings (40) housed inside the respective through-holes. The casing includes at least two spacers (50), equal in number to the number of through-holes, applied on the base surface of the flange portion opposite the respective though-holes. Each spacer includes a bushing (51) and a collar (52) coaxial with the bushing. The casing includes at least two inserts (60), equal in number to the number of spacers, housed with interference inside the respective metal bushings and spacers.