DE19614613A1 - Plain bearing with horizontally divided housing - Google Patents

Abstract

In the horizontally divided housing (4) are formed hollow, spherical part-faces (12,14), in which is swivelable a bearing shell (18) with at least one spherical part-face, about a ball centre point (22). The hollow, spherical part-faces are formed on several pole shoe-like protrusions (28,30). The protrusions extend from a housing peripheral part (4,10) inwards in the direction of the bearing rotation axis (6). The protrusions are mutually spaced peripherally round the bearing rotation axis, limiting cavities in between.

Description

The invention relates to a plain bearing according to the Preamble of claim 1.  

The object of the invention is to be achieved train the plain bearing so that it is a has less weight and that at the same time Access to the inside of the bearing housing improved to make more space inside the case mechanical manufacture of the housing and for cleaning of the housing.

This object is achieved according to the invention by the Features of claim 1 solved.

By the invention, the weight of the housing smaller and it has better access to that Housing inner for mechanical processing of the Housing interior and for cleaning the Housing interior. There is also the advantage that the hollow spherical segment surfaces of the housing, in which the bearing shell around a ball center is pivotally mounted on easier and cheaper way with one layer made of electrically insulating material can be closed as a ring Partial hollow spheres. So that can easily Bearing housing from the bearing shell electrically be isolated. Need for warehouse production only housing made without electrical insulation to be as the insulation as needed retrospectively in the Hollow spherical partial surfaces of the housing can be used. The housing and the bearing shell are made  preferably made of metal, but there are also others Materials, such as plastic, can be used. When using plastic, the the aforementioned electrical insulation is not required. According to another preferred Embodiment according to the invention is at least one of the pole-like projections according to the Claims relative to the housing and radially to Bearing axis of rotation adjustable and there are means provided to adjust this projection. By this embodiment can the bearing shell between the pin-like protrusions are pinched, after the bearing shell realtively to the housing was positioned.

According to the invention are between the pole-like Protrusions formed cavities that overlap at least 15 degrees around the bearing axis of rotation extend. According to a preferred embodiment the cavities each extend over 90 degrees the bearing axis of rotation. Larger angles are also possible. The smaller the angles, the less is the material saving and the smaller it is the access cross section into the interior of the housing.

According to another preferred embodiment of the Invention is the bearing shell in an axial Level divided so that it consists of two shell halves consists. This has the advantage that there are waves in it or other rotational bodies can be placed which on both axial sides of the bearing shell  a collar, a gear or similar radial Have a head start.

The plain bearing according to the invention can be a pure one Radial bearing. Through its hollow spherical segment-shaped and its complementary to it Partial-spherical seats between the However, the housing and the bearing shell can also Take up axial forces. Except for these spherical ones Seating can be done in a known manner Means can be provided so that the plain bearing can absorb larger axial forces. Such means are for example on the bearing shell or on Bearing housing attached ring-shaped Plain bearing surfaces or arranged in a ring Slide shoes, the slide bearing surface in each shows axial direction.

The invention is described below with reference to the Drawing based on preferred embodiments described as examples. In the drawings demonstrate:

Fig. 1 is an exploded view of a sliding bearing according to the invention,

Fig seen. 2 is a perspective view of the sliding bearing of Fig. 1 from an end face substantially axially,

Fig. 3 is an exploded view of another embodiment of the sliding bearing according to the invention,

Fig. 4 is a perspective view of the plain bearing of Fig. 3 seen from one end side essentially in the axial direction.

The sliding bearing 2 shown in Figs. 1 and 2 has a housing 4 which is divided in a horizontal, lying in a bearing axis of rotation 6 dividing plane into a lower housing part 8 and an upper housing part 10. In each housing part 8 and 10 , a hollow spherical segment surface 12 or 14 is formed, each of which extends over approximately 70 degrees around the axis of rotation 6 and is diametrically opposed to one another. They form the seat for receiving an annular spherical partial surface 16 of a bearing shell 18 which, according to an arrow 20 , can be inserted into the housing 4 between its seat surfaces or hollow spherical segment surfaces 12 and 14 and can be pivoted therein about a ball center 22 relative to the housing 4 . In this way, the bearing shell 18 can be aligned with the longitudinal direction of a shaft to be supported in it. The bearing axis of rotation 6 is the central axis of a bearing shell bore 24 , in which the bearing shell 18 is provided with a bearing running surface 26 . A shaft mounted in the bearing running surface 26 can rotate relative to the bearing shell 18 about the bearing axis of rotation 6 .

The hollow spherical segment surfaces 12 and 14 , which form the seat surfaces of the housing 4 for the bearing shell 18 , are formed on two radially inwardly facing pole shoe-like projections 28 and 30 , of which the lower 28 is formed integrally with the lower housing part 8 , during the upper 30 is connected to the upper housing part 10 by a set screw 32 and is radially adjustable relative to the lower pole shoe-like projection 28 opposite it. Due to this radial adjustability of at least one of the two pole shoe-like projections 28 and 30 , the bearing shell 18 can be clamped between them after it has been aligned with the axis of rotation of a shaft mounted in it.

The pole shoe-like projections 28 and 30 of the housing 4 are spaced apart from one another in the circumferential direction about the axis of rotation 6 and delimit cavities 34 between them. In the embodiments of the drawings, the cavities 34 each extend over 110 degrees about the axis of rotation 6 . So that a usable space 34 is formed between the pole shoe-like projections 28 and 30 , the cavities should extend at least 15 degrees in the circumferential direction around the axis of rotation 6 .

According to modified embodiments, three or more such projections can also be provided instead of two pole shoe-like projections 28 and 30 . However, according to the drawings, the preferred embodiment has only two pole shoe-like projections 28 and 30 , because as a result a largest possible cavity 34 can be formed between them. The radial depth of the cavities 34 is preferably made as large as possible and should be several millimeters. As the drawings show, the circumferential cavities 34 do not have to be segment-shaped, but they can have any other shape, for example expanded in a polygonal manner in accordance with the drawings in the lower housing part 4 .

According to the drawings, the bearing shell 18 is preferably divided into two identical bearing shell halves 38 and 40 in an axial plane 36 . As a result, shafts can also be mounted in their bearing running surface 26 , which axially have a shaft collar, a gearwheel or another radial projection on both sides of the bearing shell 18 .

The embodiment according to FIGS. 3 and 4 is identical to the embodiment according to FIGS. 1 and 2 with the exception that all pole shoe-like projections 28 and 30 are formed in one piece with the housing 4 , the lower projection 28 being integral with the lower housing part 4 and the upper projection 30 is formed integrally with the upper housing part 10 . The housing 4 is preferably made of cast metal. The bearing shell 18 is preferably also made of metal. However, some of these metal parts can instead be made of another material, for example the bearing shell 18 made of plastic.

All embodiments have the advantage that their bearing seat surfaces, which are formed by the hollow spherical segment surfaces 12 and 14 of the housing 4 and by the annular spherical partial surface 16 of the bearing shell 18 , in a simple manner during production or only later with an electric one Insulating layer 42 can be provided in order to electrically isolate the housing 4 from the bearing shell 18 .

Each hollow spherical segment surface 12 and 14 of the housing 4 is preferably continuously smooth, as shown in the drawings. In a modified embodiment, they can be interrupted by partially ring-shaped grooves that extend in the circumferential direction about the axis of rotation 6 .

Claims (5)

1. plain bearing containing a horizontally divided housing ( 4 ) in which hollow spherical partial surfaces are formed; a bearing shell ( 18 ) with at least one spherical partial surface, with which the bearing shell ( 18 ) in the hollow spherical partial surfaces of the housing ( 4 ) can be pivoted about a spherical center point ( 22 ); characterized in that the hollow spherical partial surfaces ( 12 , 14 ) are formed on at least two pole shoe-like projections ( 28 , 30 ) which extend inwards from a housing peripheral part ( 4 , 10 ) in the direction of the bearing axis of rotation ( 6 ) ; and that the projections ( 28 , 30 ) in the circumferential direction around the bearing axis of rotation ( 6 ) are spaced apart and delimit cavities ( 34 ) lying between them. 2. plain bearing according to claim 1, characterized in that the bearing shell ( 18 ) is divided in an axial plane ( 36 ). 3. plain bearing according to one of the preceding claims, characterized in that the cavities ( 34 ) each extend in the circumferential direction over at least 15 degrees. 4. Slide bearing according to one of the preceding claims, characterized in that at least one of the pole-like projections ( 28 ) with the housing ( 4 ) is integrally formed. 5. Slide bearing according to one of the preceding claims, characterized in that at least one of the pole-like projections ( 30 ) relative to the housing ( 4 ) and radially to the bearing axis of rotation ( 6 ) is adjustable and that means ( 32 ) are provided for adjusting.