DE2159417A1 - Linear slide bearing inserts - produced on jig and in situ - Google Patents

Abstract

Jig for holding slide block insert blanks for linear bearing blocks comprising multi sliding surface radial bearings with several bearing block inserts supported in a ring, the slide blocks inserts having a greater curvature than the shaft to be supported so as to produce lubricant wedge gaps, comprises a symmetrical polygon cross section, the polygon sides, of which are fitted with a stud for screwing the blanks on. All studs are coplanar in a plane perpendicular to the axis of symmetry of the polygon and its outer sides. The jig is used in the first production stage of the inserts for generation of their cylindrical backing surfaces, the working surfaces being machined in the final ring holder in situ. The method ensures the production of well aligned well fitting inserts.

Description

Device and method for the production of bearing blocks for a The invention relates to multiple sliding surface radial bearings and bearing block blank therefor initially on a device for holding bearing block blanks in the Manufacture of bearing blocks for a multiple sliding surface radial bearing, which has several has bearing blocks held in a support ring, the sliding surfaces of which are used for formation of lubricating wedge gaps have a larger radius of curvature than one to be stored in them Shaft, further to a method for the production of such bearing blocks and finally on a bearing block blank.

from which a bearing block can be produced.

It is already known (DT-OS 1,813 781), a multi-slide bearing to be built in such a way that a support ring has several bearings.

picks up blocks, the sliding surfaces of the bearing blocks a little have a larger radius of curvature than a shaft to be mounted in it, so that lubricating wedge gaps result, which generate a hydrodynamic load-bearing force when the shaft rotates.

In a manufacturing method of the known multiple sliding surface bearing blind holes are worked into the support ring and inserted into the bearing block blanks then on the inwardly facing surfaces of the bearing block blanks a common, interrupted cylinder surface is produced, whose Radius is larger than that of the shaft to be supported This results in the individual Sliding surfaces of the bearing blocks. Between the backs of the finished bearing blocks and the bottoms of the blind holes are then each a spacer in the form of a film inserted by the thickness of the desired eccentricity. The bearing surfaces of the bearing blocks now represent a common bearing for the shaft, whereby the offset of the bearing blocks form the lubricating wedge gaps around the thickness of the spacers.

By contrast, the present invention is intended to achieve that go through a relatively simple manufacturing process and an associated device the radial heights of the bearing blocks produced within such tight tolerances are the same that the bearing blocks can be exchanged individually or in sets.

Such an accuracy would be in the known multiple sliding surface radial bearings can only be achieved if the depths of the blind holes are achieved with the required depth To maintain accuracy. This would be so costly that one would then dispense with an interchangeability of the bearing blocks and, if necessary, bearing blocks would have to fit individually.

The task at hand is achieved with a device of the type mentioned at the outset solved according to the invention in that (characteristic of claim 1).

Using such a mandrel the production of Bearing blocks carried out in an advantageous development of the invention in such a way that ....... (characteristic of claim 3).

Here, too, spacers are used to move the bearing blocks inward used. The greater precision in the radial dimensions of the bearing blocks will achieved in that the bearing blocks are made on a mandrel that for a large number of bearing blocks to be manufactured only needs to be manufactured once, so that the considerable effort for the necessary precision is justifiable here. Further no blind holes, but an inner ring groove are made in the support ring, what can be achieved with high precision without difficulty by a turning process leaves.

Bearing blocks produced in this way can be used for standardized shaft diameters kept in stock and exchanged quickly and at low cost in the event of repairs will.

The annular groove expediently has a cylindrical outer surface, however, the protected area should also include other rotationally symmetrical outer surfaces, E.g. those that are inclined inwards or outwards from the edge to a median plane or curved.

The bearing block blanks are preferably given such a radial thickness that the threaded holes to be produced first when turning the sliding surfaces disappear completely, so that the sliding surface of each bearing block does not penetrate any hole is interrupted.

An embodiment of the invention is described below with reference to the Drawing described.

Fig. 1 shows a perspective view of a manufactured according to the invention Multi-sliding surface bearing with four bearing blocks.

Fig. 2 and 3 show a perspective view of a bearing block in essential from the outside or inside.

Fig. 4 shows part of the bearing in section along a radial Middle plane.

Fig. 5 and 6 show a bearing block blank in partially sectioned Side view or in plan view from the direction A in FIG. 5.

Fig. 7 shows a bearing block loop after completion of the on the mandrel carried out manufacturing steps.

8 and 9 show the mandrel with two screwed-on bearing block blanks in views perpendicular to its axis of symmetry or in the direction of its axis of symmetry.

Fig. 1 shows a multiple sliding surface radial bearing produced according to the invention with a support ring 4. This has an inner annular groove 5 with a cylindrical Seat 7 and radial, flat side surfaces 6. There are four tag blocks in the annular groove 8 are used, one of which can be seen in full and two in part. Between Bearing blocks and the The outer surface of the annular groove 6 is located each a spacer which is not visible in FIG. The bearing blocks are with Screwed with the help of hexagon socket screws lo with the bearing body and the support ring. Openings 12 are used to supply lubricant.

The shape of the bearing blocks can be seen more clearly from FIGS. 2 to 4. The sliding surface 14 is a partial cylinder surface, the radius of curvature of which by the thickness the spacer to be inserted is larger than the radius of the shaft to be supported.

The bearing block has a cylindrical outer surface on its rear side 16, the radius of curvature of which is smaller than the radius by the thickness of the spacer washer the seat 7 of the annular groove. To prevent the bearing blocks from twisting within the annular groove To prevent this, the bearing blocks are on two opposite sides with flat, mutually parallel mating surfaces 18 are provided. Their mutual distance is so large that the outer parts of the bearing blocks almost free of play in the annular groove 5 fit in.

In the middle of the outer surface 16 is a threaded hole 30 (Fig. 4) intended to accommodate the hexagon socket screw lo. The hole has a counterbore 28, in which a sleeve-shaped centering ring 24 or a (longitudinally slotted) clamping sleeve is inserted, whereby a displacement-free seat of the bearing blocks in the support ring is guaranteed.

4 shows the spacer between the bearing block 8 and the support ring 4 26 and the seat of the clamping ring 24 in the associated counterbore 28 of the bearing block.

Fig. 5 shows a bearing block blank in side view and partially in section 34. It has a flat contact surface 35 and a central, perpendicular to the contact surface, inner threaded hole 36, which is only used for attachment to the mandrel. After all operations to be carried out on the mandrel are completed and the bearing block blanks in the annular groove 5 of the support ring 4 are attached, this becomes the inner threaded hole 36 surrounding material is removed when the sliding surface 14 is turned out, so that the inner The threaded hole disappears.

Viewed in direction A in FIG. 5, the bearing block blank can accordingly Fig. 1 to 3 be circular. But it can also be rectangular according to FIG. 6 and have beveled corners or other shapes.

FIG. 7 shows a bearing block blank in a side view corresponding to FIG. 5, which still has its inner threaded bore 36 and the material surrounding it, but already with its outer surface 16, its lateral mating surfaces 18 and his outer threaded hole 30 is provided.

8 and 9 show the mandrel 40 with two attached bearing block blanks 34, namely in FIG. 8 in side view, and in FIG. 9 in front view, in the direction of the arrow B in FIG. 8.

The mandrel 40 here has a square cross-section, as shown in FIG. 9. and is provided with a threaded pin 44 in the middle of each of its lateral surfaces 42. Should the bearing not have four bearing blocks, as in the present case, but e.g. six or eight, the mandrel has a regular cross-section Hexagon or octagon etc.

for other numbers of bearing blocks. In any case it should mandrel can accommodate a set of bearing blocks. There are four set screws 44 on the four Bearing block blanks 34 screwed on. The mandrel has two cylindrical ones to his Axis of symmetry 45 rotationally symmetrical clamping pieces 46, each with a centering hole 47 for clamping in a lathe.

The bearing blocks are made as follows: First, from Bearing material in the form of a rod, round material or a rod with a cross-sectional shape e.g.

according to-Fig. 6 four blocks cut off or cut off, which form the bearing block blanks 34 form. In the case of large bearings, it is preferable to use pre-cast round pieces. Then, from one end face, the inner threaded hole is made in each bearing block blank 36 introduced. The four bearing blocks are then with this threaded hole on the Threaded pins 44 of the dome 40 are screwed on, as shown in FIGS. 8 and 9. Then will on the lathe in which the mandrel is clamped, but the common but interrupted, cylindrical outer surface 16 and the lateral mating surfaces 18 turned to the blanks.

While the mandrel is on the lathe, the outer Threaded holes 3q made for fastening the bearing blocks 8 in the support ring 4 serve. This is advantageously done by a drill on the support the lathe: is fastened so that the drill is directed against the axis of rotation. Likewise be. the counterbores 28 milled with the aid of the drill.

The blanks are now unscrewed from the mandrel 40 and in the annular groove 5 of the support ring 4 is initially attached without the spacers 26. Because the radius the outer surfaces 16 is slightly smaller than the radius of the cylindrical seat surface 7 of the ring groove, the bearing blocks must be prevented from tilting in the ring groove.

For this purpose, the bearing blocks are hardened with a fast Glue in such a way that the wedge gaps are filled. An adhesive is chosen which, after hardening, becomes so rigid and firm that it adequately supports the bearing block blanks can support, but on the other hand allows easy removal of the bearing blocks and is easily removable itself. The bearing blocks are immediately after being painted on of the adhesive using the centering rings 24 and the Allen screws lo tightened in the support ring 4.

The support ring 4 is now clamped in the chuck of a lathe, and the sliding surfaces 14 of the bearing blocks are called 'parts of a common cylinder surface manufactured. The radius of this cylinder surface is around the thickness of the spacer washers 26 larger than that of the shaft to be supported. Then the bearing blocks are aus'dem Support ring 4 removed. The glue is removed. Then the bearing blocks are under Insertion of the spacers 26 and the centering rings 24 back into the support ring inserted and screwed tight.

Claims (5)

P A T E N T A N S P R U C H E 1. Device for holding bearing block blanks during manufacture of bearing blocks for a multi-sliding surface radial bearing, several in one support ring Has supported bearing blocks, the sliding surfaces of which form lubricating wedge gaps have a larger radius of curvature than a shaft to be stored in it, thereby ge k e n n -z e i c h n e t that the device has a prismatic mandrel (40) has the cross-section of an equilateral regular polygon, which is the temporary Admission of bearing block blanks (34) for processing their rotationally symmetrical Outer surfaces (16) on each of its lateral surfaces (42) has a threaded pin (44), and that the axes of the threaded pins are radially in a common imaginary plane are perpendicular to the axis of symmetry and to the lateral surfaces of the mandrel. 2. Device according to claim 1, characterized in that the number the outer surface of the mandrel is equal to the number of bearing blocks of the bearing. 3.) Process for the production of bearing blocks for a multi-sliding surface radial bearing, which has several bearing blocks held in a support ring, the sliding surfaces of which to form lubricant wedge gaps have a larger radius of curvature than one Shaft to be stored therein, using a device according to claim 1 or 2, characterized in that the bearing block blanks (34) each with a flat contact surface (35) and perpendicular to it in the center with a threaded hole (inner threaded hole 36) are provided with which they each on one of the threaded pins (44) to the firm contact of their contact surfaces on the lateral surfaces (42) of the mandrel be screwed that while rotating the mandrel about its axis of symmetry (45) the bearing block blanks by machining a common, interrupted, rotationally symmetrical (in particular cylindrical) outer surface (16) is produced, whose radius is smaller than that of a seat (7) for the bearing blocks (8) within an inner annular groove (5) of the support ring (4) that the bearing block blanks are lateral Mating surfaces (18) and an external threaded bore (30) received, then with their outer surfaces (16) and lateral, namely, mating surfaces inserted into the annular groove to prevent it Glued in by tilting movements and fastened from the outside by a screw (lo) be that by machining on the bearing block blanks a common, interrupted, circular cylindrical sliding surface (14) is generated, the inner radius of which larger than the radius of the shaft to be supported, and that to achieve the lubricating wedge gaps then between the finished bearing blocks and the seat of the annular groove spacers (26) should be inserted. 4. The method according to claim 3, characterized in that the outer Threaded bores (30) each receive a counterbore (28) into which a clamping sleeve or a centering ring (24) can be fitted (Fig. 4). 5. Bearing block blank for machining according to a manufacturing process according to claim 3 or 4, characterized in that its radial initial dimensions and the depth of its inner threaded bore (36) are so great that during manufacture the sliding surface (14) completely removes the material surrounding the inner threaded hole will. L e r s e i t e