DE3736390A1 - Sliding-bearing arrangement - Google Patents

Abstract

In a sliding-bearing arrangement with a radial sliding bearing 12a and an axial (thrust) sliding bearing 12b, the axial sliding bearing 12b too is supplied with fresh cooled lubricant, it being possible for this lubricant to be mixed with the hot lubricant emerging at the end of the radial sliding bearing 12a. For this purpose, the axial sliding bearing 12b is equipped with at least one lubricant hole 18 which opens into at least one lubricant groove formed in the sliding surface 16 of the axial sliding bearing and extending over the entire width of the axial sliding bearing and is connected to a lubricant passage 20 in the bearing block 11 to allow the cooled fresh lubricant to be fed in. The lubricant passage 20 leading to the axial sliding bearing 12b can be branched off from the lubricant passage 14 leading to the radial sliding bearing 12a in the interior of the bearing block and can contain a flow restrictor 21 to establish as desired lubricant distribution ratio between the radial sliding bearing 12a and the axial sliding bearing 12b. <IMAGE>

Description

The invention relates to a plain bearing arrangement with a radial plain bearings inserted in a bearing bracket and min least an axial plain bearing, especially with a Flange bearing, in which the radial plain bearing lubricant at least one lubricant installed in the bearing bracket channel supplied and attached by means of a radial slide bearing brought lubricant supply distributed in the sliding surface becomes.

In the known slide bearing arrangements of this type, the lubricant supply to the axial slide bearing is provided by the hot lubricant emerging from the radial bearing on the end face. For this purpose, the axial plain bearing in the known and customary plain bearing arrangements is provided in its sliding surface with lubricant grooves extending from the inner edge to the outer edge of the axial plain bearing, through which the lubricant coming from the radial plain bearing is to flow and from where it is to be partially distributed to the sliding surface of the axial plain bearing. This conventional lubricant supply of the thrust plain bearing in such plain bearing arrangements is used consistently, regardless of whether it is the thrust bearing part of flange bearings, thrust washers mechanically anchored to the radial bearing part or thrust washers attached to the bearing block independently of the radial bearing part. In any case, the above-mentioned conventional lubricant supply to the thrust bearing or thrust bearing part is deficient, primarily due to the fact that the lubricant coming from the radial bearing part is already hot and causes heating rather than cooling of the thrust bearing. Furthermore, contributes to the inadequate supply of lubricant to the thrust bearing that the lubricant coming from the radial bearing very quickly passes through the lubricating grooves provided in the sliding surface of the axial sliding bearing without reaching the sliding surface of the axial sliding bearing in sufficient quantity for the hydrodynamic effectiveness. In order to allow lubricants in such an amount to pass through the lubricant grooves in the sliding surface of the axial sliding bearing in order to allow lubricant to pass onto the sliding surface, only a few lubricant grooves have so far been provided in the axial sliding bearing. This in turn results in a poor, width-to-length ratio ( B / L ratio) of the sliding shoes resulting from the subdivision of the sliding layer by means of the lubricant grooves on the axial sliding bearing, with the additional fact that due to the curvature of these sliding shoes the lubricant prematurely emerges laterally from the Slide shoe is promoted. All this results in the conventional Gleitlageran orders that the axial slide bearing, for example, in the axial bearing of crankshafts in machines, with strong mixed friction can be expected, which places high demands on the bearing material and always leads to failure and damage to the leads both sliding partners.

In contrast, the object of the invention is to reduce the mixed friction conditions an improved lubricant supply to the axial plain bearing from above To create plain bearing arrangements, while improving Heat dissipation on the axial plain bearing is to be achieved and the manufacturing expenditure should hardly be increased.

This object is achieved according to the invention in that the axial plain bearing with at least one lubricant bore is provided in at least one in the sliding surface of the axial sliding bearing or lubricant groove middle pocket opens and a formed in the camp chair Lubricant channel is connected. This will make the axial plain bearing in addition to that coming from the radial plain bearing Lubricant also fed directly cooled lubricant, whereby not only those fed to the radial slide bearing  Lubricant amount increased, but also the lubricant temperature is reduced. It can now go through the increased amount of lubricant also on the axial plain bearing Form a hydrodynamically effective lubricant film. The Mixed friction conditions on the axial plain bearing become considerable reduced.

In a preferred embodiment of the invention, at least one lubricant supply groove connected to the lubricant bore is attached to the back surface of the axial slide bearing and is opposite the exit of a lubricant channel in the bearing block. This lubricant supply groove can extend over a considerable part of the circumferential length of the axial slide bearing and can be connected to a plurality of lubricant bores. As a result, the number of lubricant grooves in the sliding surface of the axial sliding bearing can be increased ver, whereby the B / L ratio of the sliding shoes formed in the sliding surface of the axial sliding bearing is improved. For example, a B / L ratio of B / L = 1 can be achieved in this way. By such an improvement in the B / L ratio, the partial influence of the curvature of the sliding shoes is reduced and possibly negligibly small, so that a hydrodynamically effective lubricant film can form practically over the entire sliding shoe surface.

These particularly advantageous conditions of lubrication Medium supply on the axial plain bearing can be done in the frame achieve the invention particularly cheap if the Lubricant supply groove over the entire circumferential Length of the axial plain bearing extends and from this Lubricant supply groove in predetermined mutual angular distances to one lubricant lubricant hole in the sliding surface are mounted in axial plain bearings. The  Sliding surface of the thrust bearing by a plurality of itself over the entire width, preferably essentially radial, extending lubricant grooves into a plurality of Fields can be divided into types of sliding shoes, one Number of these lubricant grooves, preferably each lubricant middle groove, via a lubricant hole to the Lubricant extending circumferentially to the axial plain bearing Supply groove is connected. However, it is not absolutely necessary, every lubricant groove of the axial slide bearing via a lubricant hole to the lubricant Connect the supply groove. In the interest of if possible unimpeded outflow of the coming from the radial plain bearing and used for the lubrication of the axial plain bearing In some applications it is even a lubricant desirable, also such lubricant grooves in the sliding to provide the surface of the thrust bearing, which is not connected to the Lubricant supply groove are connected.

A particularly simple and advantageous embodiment the invention provides that the or the to the lubricant leading to the axial sliding bearing channels from the lubricant leading to the radial plain bearing channel is or are branched. However, to avoid that the lubricant supply to the radial plain bearing through a noticeable lubricant thus formed short circuit could worsen exists in the frame the invention, the possibility of the Axial lubricant channels leading to plain bearings at least in part to be equipped with a flow restrictor.

An embodiment of the invention is as follows explained in more detail with reference to the drawing. Show it:

Fig. 1 is a slide bearing assembly according to the invention with collar bearing (without showing the mounted shaft) in an axial partial section;

FIG. 2 shows a flange bearing bush that can be inserted into a slide bearing arrangement according to FIG. 1 in a side view according to arrow 2 in FIG. 1; and

Fig. 3 shows a modified, according to the invention flange-bearing bushing in a corresponding view as FIG. 2.

The examples shown are a slide bearing arrangement 10 for the crankshaft, which is attached in the cylinder block of a piston engine. The slide bearing assembly 10 includes a bearing block 11 , on which two crankshaft collar bearings 12 each with radial slide bearing 12 a and one or two axial slide bearings 12 b are placed. The radial slide bearing 12 a has a lubricant bore 13 , which is arranged in the center in a conventional manner and overlaps with the outlet of a lubricant channel 14 formed in the bearing block. The axial slide bearing 12 b has in the examples shown extending over its entire radial width B lubricant grooves 15 which are arranged radially in the example of FIG. 2 and in the game of FIG. 3 in groups parallel to each other but essentially radial. The latter arrangement is easier to manufacture in terms of production technology. Instead of the orthogonal to each other provided in FIG. 3, the course directions of the lubricant grooves 15 could also be groups in which the course of the lubricant grooves 15 is directed at 45 ° to one side and the other. Between the lubricant grooves 12 b fields are formed in the sliding surface 16 of the axial sliding bearing, which represent sliding shoes 17 . In the examples shown, these sliding shoes 17 have an average circumferential length L , which is approximately the same size as the radial width B of the axial sliding bearing 12 b .

The supply of lubricant to the axial sliding bearing 12 b takes place on the one hand through the lubricant emerging from the end of the radial sliding bearing 12 a , which is taken up by the lubricant grooves 15 of the axial sliding bearing and is guided outward over the width B of the axial sliding bearing. Part of this lubricant passes over the edge of the lubricant grooves 15 on the respective slide shoe 17th In addition, a supply of chilled, fresh lubricant is made. 12 For this purpose, the sliding thrust bearings b in all lubricant grooves 15 (Fig. 2) or in a number of its lubricant grooves 15 (Fig. 3) an opening into a respective lubricating central groove 15 lubricant bore 18. All lubricant holes 18 are on the back of the axial sliding bearing 12 b with a lubricant supply groove 19 in connection, while in the bearing block 11 at least one lubricant channel 20 is provided for each axial sliding bearing 12 b . This lubricant channel 20 leads to the lubricant supply groove 19 . In the example in FIG. 1, two lubricant channels 20 are provided, one for each of the two axial slide bearing parts of the flange bearing shell 12 . The two leading to the axial sliding bearings 12 b lubricant channels 20 are branched in the bearing block 11 from the leading to the radial sliding bearing 12 a lubricant channel 14 . In order to avoid that the lubricant pressure in the radial friction bearing 12 a may decrease excessively due to the b to the axial thrust bearings 12 derived lubricant are in the b to the axial thrust bearings 12 leading lubricating fluid channels 20 each have a flow restrictor 21 used, which is schematically shown in Fig. 1 . The about the additional lubricant channels 20 in the bearing block 11 and the lubricant supply groove 19 on the back side of the axial sliding bearing 12 b, and finally the lubricant holes 18, introduced into the lubricant grooves 15 fresh, cooled lubricant is mixed with the stock from the Radialgleit 12 a coming hot lubricant and thereby causes an improved cooling on the axial plain bearings 12 b . In addition, it increases the amount of lubricant available at the respective axial slide bearing, so that an increased amount of lubricant passes over the edge of the lubricant grooves 15 onto the sliding surface 16 or the bearing shoes 17 formed on it. The amount of lubricant thus reaching the sliding surface 16 or the bearing shoes 17 is suitable for building up a hydrodynamically effective lubricant film. Due to the close arrangement of the lubricant grooves provided in the examples of FIGS. 2 and 3, the ratio of the radial width B and the circumferential length L of the sliding shoes 17 is substantially improved and in these two examples is approximately B / L = 1. Through this improved B / L ratio in conjunction with the increased made available amount of lubricant and the lowered lubricant temperature, the mixed friction relationships are b in such a manner reduces the axial sliding bearing 12 so as to correspond to Wesent union the mixed friction conditions at the radial bearings 12 a.

Reference symbol list:

10 plain bearing arrangement
11 camp chair
12 a radial plain bearing
12 b thrust plain bearings
13 lubricant hole
14 lubricant channel
15 lubricant grooves
16 sliding surface
17 sliding shoe
18 lubricant hole
19 lubricant supply groove
20 lubricant channels
21 flow restrictor

Claims (7)

1. Plain bearing arrangement with a radial slide bearing inserted into a bearing block and at least one axial slide bearing, in particular flange bearing, in which lubricant is supplied to the radial slide bearing through at least one lubricant channel provided in the bearing block and is distributed in the sliding surface by means of a lubricant supply provided in the radial slide bearing, thereby characterized in that the axial sliding bearing ( 12 b ) is also provided with at least one lubricant bore ( 18 ) which opens into at least one lubricant groove ( 15 ) or lubricant pocket formed in the sliding surface ( 16 ) of the axial sliding bearing ( 12 b ) and to one in the bearing block ( 11 ) formed lubricant channel ( 20 ) is connected. 2. Plain bearing arrangement according to claim 1, characterized in that on the back surface of the axial sliding bearing ( 12 b ) at least one with the lubricant bore ( 18 ) communicating with the lubricant supply groove ( 19 ) is attached, which is the output of a lubricant channel ( 20 ) in the bearing block ( 11 ) is compared. 3. plain bearing arrangement according to claim 1 or 2, characterized in that the lubricant supply groove ( 19 ) extends over the entire circumferential length of the axial sliding bearing ( 12 b ) and from the lubricant supply groove ( 19 ) at predetermined mutual angular intervals Lubricant bores ( 18 ) in the axial sliding bearing ( 12 b ) are provided in each of one lubricant groove ( 15 ) in the sliding surface ( 16 ). 4. Plain bearing arrangement according to claim 3, characterized in that the sliding surface ( 16 ) of the axial plain bearing ( 12 b ) is divided by a plurality of lubricant grooves ( 15 ) extending over its entire width into a plurality of fields in the manner of sliding shoes ( 17 ) wherein a number of these lubricant grooves (15), preferably each lubricant groove is connected via a lubricating bore (18) to the circumferentially extending the axial slide bearing (12 b) lubricant supply groove (19). 5. Plain bearing arrangement according to one of claims 1 to 4, characterized in that the mutual distance ( L ) of the lubricant grooves ( 15 ) in the sliding surface of the axial plain bearing ( 12 b ) is approximately the same as the radial width ( B ) of the axial plain bearing ( 12 b ) . 6. Plain bearing arrangement according to one of claims 1 to 5, characterized in that in the bearing block ( 11 ) leading to the or the axial sliding bearings ( 12 b ) leading lubricant channel ( 20 ) or lubricant channels from or to the radial sliding bearing ( 12 a ) leading lubricant channel ( 14 ) or lubricant channels is branched. 7. plain bearing arrangement according to claim 6, characterized in that the leading to the or the axial plain bearings ( 12 b ) leading lubricant channels ( 20 ) are at least partially equipped with a flow restrictor ( 21 ).