DE629859C - Pressed material plain bearings - Google Patents

Description

The general application of bearing shells and bushings made of synthetic resin molded materials opposed to the low thermal conductivity and the difficult connection of this bearing material with support shells or Wrestling. The usual molded bushing forms a heat insulator around the Shaft, so that the frictional heat can not be transferred to the housing, but must be discharged via the shaft. The thermal equilibrium of such bearings arises therefore, it is already activated with a low load, unless special cooling is provided.

If the pressed material ring is applied to the shaft and runs with it in a special way Outer ring around, the frictional heat is transferred directly to the housing, and the Preßstoffring locks like a Heat insulator transports heat to the shaft so that it remains relatively cold. According to experience however, the pressed material ring comes off the shaft when heat is absorbed during operation of the bearing, because synthetic resin pressed substance has a much greater coefficient of thermal expansion than Stole.

The detachment of the pressed material ring from the shaft is avoided if this is with a Support ring made of steel is permanently connected.

The steel ring can easily be attached to the shaft and lifts even with a suitable connection with the Preßstoffring whose greater thermal expansion, so that the Preßstoffring essentially only follows the thermal expansion of the steel ring.

In this way, a bearing unit is obtained which consists of the pressed steel ring as the inner ring and the outer ring. This storage unit can be used with cylindrical as well as with a spherical running surface.

In order to achieve a permanent connection of the Preßstöffs with the support ring the support ring provided with narrow, thin ring tooth ribs and the press fabric after known method by means of pressure and heat in the spaces between the ring tooth ribs pressed in so that only the base of the support ring forms the shrink base of the pressed material ring. Known swallow Tail-shaped grooves were found to be unsuitable for the intended purpose because there are two levels of shrinkage here. The outer ring is also inserted into the press die, so that the resulting annular space between the support ring and the outer ring can be fully pressed out with molding material.

In the case of bearings with a spherical sliding surface, this creates an indivisible unit, while In the case of bearings with a cylindrical sliding surface, the outer ring remains axially displaceable. That Bearing play results from the shrinkage of the

Preßstoffringes in the support ring by itself, so that the bearing is ready to use from the

Press comes. '

Since synthetic resin molded material has amorphous properties,,; » the state of tension that goes through |! Shrinkage arises, gradually lost, '^ that the pressed material ring now essentially follows the thermal expansion of the support ring. This occurs all the more perfectly, the closer ίο the ring tooth ribs are placed and the more enclose these with the pressed material ring. The ring tooth ribs still leave a thick layer of pressed material unframed, this again follows its own thermal expansion with the base of the cutting edge of the ribs. In this way bearings can be built whose clearance decreases with increasing operating temperature.

The ideas on which the invention is based are described in more detail below and illustrated in Figs. 1 to 4. It represent

Fig. Ι and 2 the longitudinal and cross-section an indivisible bearing unit with a spherical running surface,

Fig. 3 the longitudinal section of a bearing unit with a cylindrical running surface,

Fig. 4 is a longitudinal section of a compressed material bearing, which with increasing heating forms a reduced bearing play.

The press-material sliding bearing (Fig. 1 to 3) consists of the undivided support ring a, which is inextricably linked to the undivided press-material ring c pressed between the ring tooth ribs b , and also of the undivided outer ring d. The thin ring-toothed ribs l ·, the cutting edges of which are just below the

■ end of the sliding surface, are on the sides

■ tooth and Tiaben no cylindrical surfaces that would hinder the shrinking process, so that the base g of the support ring α forms the shrink base of the pressed material ring c . After the compression ring has shrunk, which already happens during the pressing process, the larger, inner part e (Fig. 3) of the compression ring is enclosed by the ring tooth ribs, so that this part must follow the thermal expansion of the support ring, while the outer, smaller part / of the pressed fabric ring of the free

Subject to expansion. As a result, the bearing play h remains largely intact beyond the pressing temperature.

. 4 shows an exemplary embodiment of a material bearing, the play of which decreases as the temperature increases. About this ^? To achieve ect, the outer thick molded material layer f, which is not enclosed in the ring tooth ribs and which is subject to free expansion, is dimensioned higher than the enclosed molded material layer I ₁ so that the largest clearance k goes back from the cold state to the smallest clearance i in the warm state. Such bearings are required, for example, for machine tools that run precisely.

Claims (4)

Patent claims: ι. Pressed material plain bearing with spherical or cylindrical sliding surface, characterized by a bearing unit, consisting of the undivided support ring (α), the undivided outer ring (d) and the undivided pressed material ring (c), pressed concentrically between the two rings, as a sliding construction material and heat insulator, which is connected to the support ring by means of annular tooth ribs is inextricably connected and forms a bearing play against the outer ring due to shrinkage. 2. Preßstoffgleitlager with spherical or cylindrical sliding surface according to claim i, characterized by thin narrow annular tooth ribs (b) on the outer circumference of the support ring (α), which completely surround the Preßstoffring. (C) S5 and permanently connect to the support ring for the purpose of reducing the Thermal expansion of the pressed material ring. 3. Ring tooth ribs according to claim 2, characterized by thin ribs in the side surfaces of which are incised ring teeth. 4. Preßstoffgleitlager according to claim I and 2, characterized by an oversized, Preßstoffring- (c) partially enclosed by ring tooth ribs, the outer, non-enclosed layer of which is more unobstructed Stretch can follow to the . Purpose of reducing the bearing clearance when at operating temperature. 1 sheet of drawings