DE102004028773A1 - Plain bearing for shaft of internal combustion engine, has expansion unit opposing operationally unfavorable changes in dimensions of gap, where expansion unit that is manufactured using light metals can be used after refining - Google Patents

Abstract

The bearing has a unit (2) to which a bearing bush (3) is allocated for accommodating a shaft. The bush (3) has a groove for supplying lubricant. A surface of the shaft and the bush define a gap (6). An expansion unit (5) opposes operationally unfavorable changes in dimensions of the gap. The expansion unit that can be manufactured using light metals can be used after refining.

Description

technical area

The The invention relates to a plain bearing for supporting a shaft, with at least one bearing element, the at least one bearing shell for Assigned to the shaft receiving, wherein the bearing shell has a groove to promote a lubricant and the surface of the shaft and the bearing shell define a gap.

State of technology

such Plain bearings are well known. The waves of internal combustion engines are usually stored in such plain bearings. For optimum lubrication the plain bearings are usually supplied with oil from the inside by means of an oil pump, which is pressed into the bearings with a certain pressure. Oil pressure is required to provide the bearings with sufficient oil since the oil in constructive necessary column drains off. A large radial gap leads too undesirable large oil drain and so to dangerous pressure drop in stock. The pressure drop can cause the lubricant film to collapse which results in faster wear of the moving elements. It is therefore for one safe operation, a sufficiently high oil pressure in the bearing necessary. In the enterprise enlarge Column in the warehouse due to heating. To the oil pressure To keep constant in the camp, is the use of pumps with increased pump power possible. Such problems occur especially in modern engines with light metal housings, where components with different thermal expansion coefficients interact.

Out The prior art is the use of cast beds / bearings in light metal crankcases to Recording the bearings known. This will be the different radial expansion and thus the gap formation process between addressed to various components. However, this is at the expense of Motor weight and manufacturing costs.

presentation the invention

Of the Invention is the object of a sliding bearing of the beginning so-called type such that always optimal operation of the plain bearing while minimizing the engine weight ensured is. The present invention solves the aforementioned object by the features of the claim 1. Thereafter, a plain bearing for supporting a shaft is marked by at least one expansion element, which is an unfavorable change counteracts the dimensions of the gap.

According to the invention is recognized have been compensated that Spaltentstehungsprozesse by expansion elements can be. In particular, it has been recognized that the use of heavy Metals that are particularly costly in terms of their thermal expansion coefficient need to be optimized can be waived. In a sophisticated way, expansion elements are used which can be made of lightweight materials to Expansion processes of necessary components to compensate.

consequently is with the sliding bearing according to the invention a plain bearing specified, with always an optimal operation at Minimizing the engine weight is possible.

In a structurally particularly favorable embodiment could the expansion element can be made of a material which has a larger thermal expansion coefficient has as the materials that make up the bearing element and the to be stored shaft are made. It is also conceivable, the expansion element Made of a material that has a higher coefficient of thermal expansion has as the material from which the bearing shell is made. Depending on the application is also conceivable for the expansion element, the bearing element and the bearing shell throughout different materials with different thermal expansion coefficients to use to counteract cleft formation processes. there is not only possible, one Magnification of a To counteract cleft, but also a reduction of the same. in this respect is realized by this embodiment in an advantageous manner, that on the use of pumps, which the lubricant pressure in complicated way to adapt to the dimensions of the gap, omitted can be.

In particularly advantageous way could be arranged at least one expansion element in the bearing shell. These Design allows a particularly compact design of the plain bearing.

in the With regard to a particularly symmetrical compensation of a column formation process could Be provided on both sides of the groove expansion elements. It is conceivable that the expansion elements are arranged in or on the bearing shell. A particularly strong connection with the bearing shell could Dehnelemente be received by these in recesses of the bearing shell are fitted.

At least one expansion element could be arranged between the bearing shell and the bearing element. It is conceivable that the expansion element extends over the entire width of the bearing element. This ensures that both the bearing element and the bearing shell are applied uniformly with force. In that regard, tilting of the bearing shell are excluded relative to the bearing element.

at this embodiment could the expansion element chambered in the bearing element between two groove walls be. This has the advantage that the expansion element is fixed and his position relative to the bearing element can not change. Furthermore, the volume change unfolds due to thermal expansion axial chambering exclusively in the radial direction their effect and thus the gap-closing effect strengthened.

the Expansion element could be associated with two sealing elements, which on both sides of the bearing shell are positioned. This embodiment has the advantage that the Lubricant, which is in the gap, held in the gap and will not exit the gap. This will be the use smaller oil pumps possible.

The Sealing elements could by a support element, which surrounds the expansion element and the sealing elements, in axial Supported direction be. This concrete embodiment ensures that the sealing elements maintain their position in case of gap-side pressurization and not be pushed out by the lubricant. This has the advantage that no lubricant can escape from the gap, even if considerable within the gap pressures occur.

The Stretching elements could be made of a polymer to a particularly cost-effective production to ensure the sliding bearing.

Conceivable is to manufacture the expansion elements of an elastomer, whereby a particularly good adaptability the expansion elements to prefabricated recesses guaranteed is.

The Stretching elements could be made of a polytretrafluoroethylene compound. This material characterized by a particularly low friction and high abrasion resistance out.

The Stretching elements could be made of a thermoplastic material.

As a general rule the equipment of the upper bearing part with expansion elements is to be preferred, because the lower part of the bearing through the top of the engine cylinder significantly higher is loaded as the bearing upper part and therefore the rigidity of the Lower bearing parts should not be reduced by expansion elements.

It are now different ways to design the teaching of the present invention in an advantageous manner and further education. On the one hand to the claim 1 subordinate claims, on the other hand, to the following explanation of preferred embodiments of the invention with reference to the drawing. Combined with the explanation the preferred embodiments The invention with reference to the drawings are also generally preferred embodiments and further developments of the teaching explained.

Brief description of the drawings

In show the drawing

1 in a sectional drawing, a sliding bearing with a shaft and a bearing element and a bearing shell, wherein on both sides of a groove in the bearing shell expansion elements are introduced,

2 a sliding bearing in which an expansion element is provided between the bearing element and the bearing shell,

3 a plain bearing in which an expansion element extends over the entire width of the bearing element,

4 a slide bearing, in which an expansion element is provided both between the bearing upper shell and the bearing element and between the bearing lower shell and the bearing element,

5 a sliding bearing with an expansion element, which sealing elements are assigned,

6 a sliding bearing in which an expansion element is surrounded by seals by a support element, and

7 a sliding bearing in which expansion elements are provided both within the bearing shell and between the bearing shell and bearing element.

Execution of the invention

1 shows a plain bearing in which a shaft 1 which are in a bearing element 2 over the bearing shell 3 is stored. The lubricant supply of the gap 6 between bearing shell 3 and wave 1 takes place via the groove 4 in the bearing shell 3 , On both sides of the groove 4 are stretching elements 5 brought in. The operation of this arrangement is as follows:
As soon as the bearing element 2 by heating stronger than the wave 1 expands, the gap grows 6 at. At the same time, the volume of the expansion elements increases due to the heating. However, these can only move in the direction of the gap 6 expand, which is filled with additional volume. This causes that by Wärmeausdeh increasing volume of the gap due to the volume increase of the expansion elements 5 is reduced or compensated. As a result, the lubricant flow is throttled through the bearing or kept constant over wide temperature ranges.

The measure limited on the top of the plain bearing. Sufficient throttling the lubricant volume flow is thereby already achieved. Too much throttling would the heat dissipation through the escaping lubricant reduce too much.

2 shows a sliding bearing with a bearing element 2 which is between groove walls 8th an expansion element 7 receives. The expansion element 7 is between bearing element 2 and bearing shell 3 positioned.

The operation of this embodiment is as follows: The bearing element expands 2 due to rising temperature, so does the volume of the expansion element 7 at the same time stronger than the volume of the groove in which the expansion element 7 between the groove walls 8th is housed. This causes the bearing shell 3 is held on the shaft and the gap 6 not growing. This measure is limited to the top of the plain bearing. Sufficient throttling of the lubricant volume flow is thereby already achieved.

3 shows an arrangement according to 2 in which the expansion element 7 without provision of limitations across the entire width of the bearing element 2 extends.

4 shows a whole slide bearing, in which both bearing upper shell 3 as well as bearing lower shell 10 each with an expansion element 7 are equipped. The stretching elements 7 extend over the entire width of the bearing elements 2 . 9 ,

This specific embodiment causes a uniform gap height along the circumference of the shaft 1 , In that regard, a uniform annular gap is achieved.

5 shows a plain bearing, wherein the bearing element 2 from the bearing shell 3 through an expansion element 7 is disconnected. The expansion element 7 are sealing elements 11 assigned, which on both sides of the bearing shell 3 are arranged.

6 shows a plain bearing, in which an expansion element 7 with sealing elements 11 is provided. Both stretching element 7 as well as sealing elements 11 be from a support element 12 surrounded by the sealing elements 11 supported in the axial direction.

7 shows a plain bearing, in the bearing element 2 and bearing shell 3 through an expansion element 7 are separated. Furthermore, the bearing shell 3 expansion elements 5 on, which are assigned to her. In that regard, a combination of the stretching elements 5 and 7 realized.

In this combination, it is particularly advantageous that by the radially inwardly disposed, highly effective expansion elements 5 the lubricant flow can already be reduced. Is it due to the radial low height of the bearing shells 3 not possible, sufficiently high expansion elements 5 accommodate radially inside, so can additionally by the externally disposed expansion elements 7 the entire gap can be brought into the optimum height range with increasing operating temperature.

Regarding further advantageous embodiments and developments of the teaching of the invention on the one hand to the general part of the description and on the other hand to the attached claims.

In conclusion, be particularly emphasized that the previously purely arbitrarily chosen embodiments for discussion only the teaching of the invention serve, but do not limit these to these embodiments.

Claims (14)

Plain bearing for supporting a shaft ( 1 ), with at least one bearing element ( 2 . 9 ), the at least one bearing shell ( 3 . 10 ) for receiving the shaft ( 1 ), wherein the bearing shell ( 3 ) a groove ( 4 ) for conveying a lubricant and the surface of the shaft ( 1 ) and the bearing shell ( 3 ) a gap ( 6 ), characterized by at least one expansion element ( 5 . 7 ), which is an unfavorable change in the dimensions of the gap ( 6 ) counteracts. Slide bearing according to claim 1, characterized in that the expansion element ( 5 . 7 ) is made of a material which has a greater coefficient of thermal expansion than the material (s) making up the bearing element ( 2 . 9 ) and / or the bearing shell ( 3 . 10 ) and / or the shaft to be stored ( 1 ) is / are made. Slide bearing according to claim 1 or 2, characterized in that at least one expansion element ( 5 ) in the bearing shell ( 3 . 10 ) is arranged. Slide bearing according to claim 3, characterized in that on both sides of the groove ( 4 ) Stretching elements ( 5 ) are provided. Slide bearing according to one of claims 1 to 4, characterized in that at least one deh element ( 7 ) between the bearing shell ( 3 . 10 ) and the bearing element ( 2 . 9 ) is arranged. Slide bearing according to claim 5, characterized in that the expansion element ( 7 ) in the bearing element ( 2 . 9 ) between two groove walls ( 8th ) is chambered. Slide bearing according to claim 5, characterized in that the expansion element ( 7 ) two sealing elements ( 11 ), which on both sides of the bearing shell ( 3 . 10 ) are positioned. Slide bearing according to claim 7, characterized in that the sealing elements ( 11 ) by a support element ( 12 ), which the expansion element ( 7 ) and the sealing elements ( 11 ), are supported in the axial direction. Slide bearing according to one of claims 1 to 8, characterized in that the bearing element ( 2 ) and the bearing shell ( 3 ) above the shaft ( 1 ) and the bearing element ( 9 ) and the bearing shell ( 10 ) below the shaft ( 1 ) are arranged. Plain bearing according to one of claims 1 to 9, characterized in that the expansion elements ( 5 . 7 ) are made of a polymer. Plain bearing according to one of claims 1 to 9, characterized in that the expansion elements ( 5 . 7 ) are made of an elastomer. Plain bearing according to one of claims 1 to 9, characterized in that the expansion elements ( 5 . 7 ) are made of a polytetrafluoroethylene compound. Plain bearing according to one of claims 1 to 9, characterized in that the expansion elements ( 5 . 7 ) are made of a thermoplastic material. Sliding bearing according to one of claims 1 to 13, characterized in that the bearing elements ( 2 . 9 ) are made of light metal.