DE102014116992A1 - Slide bearing arrangement for high-speed shafts in the automotive sector - Google Patents

Abstract

The invention relates to a sliding bearing arrangement for high-speed shafts (6) in the motor vehicle area with a stationary housing (4) in which a rotationsbewegliches ring element (8) is provided, in turn, rotatably receives the shaft (6), wherein the ring element (8 ) to the shaft (6) directed an inner contour (29) having at least three bearing surfaces (30, 32, 34), wherein the bearing surfaces (30, 32, 34) in each case with respect to the center of the ring element (8) in a direction of rotation the shaft (6) steadily decreasing radius r have.

Description

The invention relates to a slide bearing assembly for high-speed shafts in the automotive area with a stationary housing in which a rotationsbewegliches ring member is provided, in turn rotatably receives the shaft, wherein the ring member directed to the shaft has an inner contour with at least three bearing surfaces.

In a conventional sliding bearing assembly for high rotating rotating shafts, such as in an exhaust gas turbocharger, preferably a bearing with a fully floating ring member between the shaft and the stationary housing is used, which rotates at approximately half the rotational speed of the shaft. By means of a lubricant, hydrodynamic lubrication is generated at the narrowing gap between the ring element and the shaft and between the ring element and the stationary housing during operation of the exhaust gas turbocharger. This creates a desired damping of the rotating shaft at several points.

Due to the small radial gaps between the ring element and the shaft and between the ring element and the stationary housing, the viscous resistance or deceleration forces lead to an angular momentum, whereby the completely floating ring element is also set in rotation.

If it comes in an undesirable manner that in an exhaust gas turbocharger, the speed of a floating ring element of the slide bearing assembly approaches the shaft at very high speeds, with increased wear at the interfaces between the ring member and the shaft and between the ring member and the housing expected. It is also to prevent the risk arises at such high speeds of the floating ring element that dangerous vibrations occur, which can be caused by a vortex in the lubricating film and large load changes on the exhaust gas turbocharger. The concomitant reduced damping and rigidity of the shaft movement can ultimately lead to increased wear or abrasion at the interface between the ring element and the shaft.

To adequately avoid such a problem, a sliding bearing assembly in an exhaust gas turbocharger according to DE 195 39 678 A1 a fully floating ring member rotatably disposed between a shaft and a stationary housing. In one embodiment, a single oil feed passage is provided in the stationary housing and a number of radially disposed oil transfer passages are provided in the fully floating slide bearing. The angle of the housing passage is selected relative to the apertures such that oil flowing between the passages transmits an angular momentum or torque to the annular element opposite to the shaft rotation to slow the rotational speed of the annular element. Alternatively, the housing passage may be disposed radially and the apertures may be inclined at an angle relative to the housing passage to transmit an angular momentum to the ring member in a direction opposite to the direction of rotation of the shaft. The housing passage and the apertures may also be inclined relative to one another in order to transmit or generate an angular momentum or torque to the ring element in a direction opposite to the direction of rotation of the shaft. In this way, therefore, the rotational speed of the ring member can be reduced, while the damping and the rigidity of the wave motion is to be maintained, without increasing the wear on the interfaces between the radial sliding bearing and the shaft and between the radial sliding bearing and the stationary housing.

In a further embodiment of an embodiment of the apertures describes the DE 10 2012 108 973 A1 in that the channel longitudinal axis is aligned at least in a region of the mouth such that a transverse axis of the first receiving opening aligned with the aid of a virtual Cartesian axis system to the longitudinal axis of the first receiving opening forms an angle with a virtual extension of the channel longitudinal axis. The angle has a value which deviates by at least 10 ° from a value corresponding to 90 °. In other words, to produce the velocity-circumferential component, the lubricant channel should have an inclination relative to a transverse axis of a cross-sectional area of the first receiving opening, at least in the area of the orifice. Furthermore, it is not necessary that the channel longitudinal axis over an entire length of the lubricant channel is formed having the angle, but for generating the desired speed peripheral component, it is sufficient if the corresponding configuration is present in the region of the mouth.

Furthermore, so-called multi-surface radial bearings are already known from the prior art, which essentially have an elliptical, shaft-directed bearing surface. Such a usable in a transmission multi-surface radial bearing already describes the DE 101 42 303 A1 , whose characteristic feature are the deviating from usual cylindrical plain bearings, represents non-circular shape of the bearing bore. This bearing bore consists of two or more bearing surface, in particular circular arcs. The radius of the bases is larger by a certain amount than that of the shaft. Due to this difference in radius, a narrowing gap is created in each circular arc, each of which begins with its greatest width at an axially machined lubrication groove and whose narrowest point is usually in the center of the bearing surface. When the rotational movement of the shaft starts, the lubricant is drawn into the lubricating gap narrowed in the direction of rotation due to its adhesive action. Between the shaft and bearing shell, a pressure zone builds up, so that the shaft lifts off from the bearing shell and the shaft runs in the area of hydrodynamic lubrication. In addition, from the DE 10 2006 033 397 A1 a generic sliding bearing assembly for an exhaust gas turbocharger known, which should be particularly suitable for supporting the rotating at high speed shaft. Here, after deformation, an elliptical bearing surface directed toward the shaft is provided, which is movably arranged in a stationary housing. Apart from the difficult production, this slide bearing assembly still does not have the desired damping properties at high speeds.

Against this background of this invention, the object is to provide a sliding bearing assembly, in particular for a turbocharger which prevents unwanted vibrations. Furthermore, the invention has for its object to provide a cost-effective storage of the turbocharger, with the wear of the storage is minimized.

This object is achieved in that the bearing surfaces in each case with respect to the center of the ring element have a steadily decreasing in the direction of rotation of the shaft radius r.

A particularly advantageous embodiment is provided in that the ring element has an outer contour which corresponds to the inner contour, so that each bearing surface is assigned to a surface region which has a constant wall thickness and which has a transition region to the adjacent surface region. In this case, the transition region can be made uniform by radii. However, it is also possible, as shown later in the exemplary embodiment, that the transition region has a greater wall thickness. This makes it possible that the Mehrflächengleitlager is executed in the inner contour and outer contour each with three bearing surfaces, wherein the respective surface centers are distributed uniformly over the circumference. This makes it theoretically possible in the sliding bearing assembly according to the invention, in each case at three points, which are offset by 120 °, to build up a hydrodynamic pressure between the housing and the ring element and between the ring element and the shaft. As a result, a supporting pressure pad is always generated every 60 °. The fact that the sliding bearing assembly is limited to one direction of rotation, can. large forces are absorbed by the special design of the bearing surfaces. It should be noted that the more constructive trained bearing surfaces has a multi-surface bearing, the more reliable a centric position can be achieved. As a result, however, the bearing surfaces are shorter, so that the load capacity of the bearing is theoretically reduced. By providing the transition areas, however, a high load capacity is ensured and the wall thickness of the ring element can remain constant in the surface areas. By these measures, in particular a very high smoothness of the shaft is possible, resulting in significantly reduced wear. As a result, changing the shaft during load makes it less likely to come in contact with something that is caused by wear on the shaft. Compared to a conventional plain bearing arrangement with a constant circular cross-section inside and outside, as in 1 Thus, the use of the wave can be kept to a minimum. Thus, the total bearing clearance of the bearings can be reduced again, so that the oil consumption of the bearing can be minimized.

A method of making such a bearing assembly may be sintering. Thus, this manufacturing process can be used to produce a high-precision part that does not need to be reworked. Furthermore, it is possible to combine various metals in the powder state before sintering the plain bearing. Another method of making such a bearing assembly may be continuous casting or extrusion.

Another method of making such a bearing assembly may be by forming a tubular cross-section. A more cost-effective primary forming process can pay attention to greater precision in post-processing.

Characterized in that a bearing system with two sliding bearing assembly is formed as a one-piece component, a higher load compared to a conventional slide bearing assembly is possible and it is a cheaper and more compact design of the slide bearing assembly possible. In addition, it is advantageous that the installation effort can be reduced by a one-piece design.

Advantageously, the ring element has openings through which the lubricant passes between the shaft and the ring element. Particularly advantageous is the use of the sliding bearing assembly according to the invention in an exhaust gas turbocharger. As a result, even smaller gaps are possible between the compressor and turbine wheels and the exhaust gas turbocharger housing, whereby the overall efficiency of the turbocharger can be significantly increased, as arise over larger gaps flow losses in the exhaust gas turbocharger. Due to the better centering of the shaft in the slide bearing arrangement with internally and externally provided multi-surface bearing surfaces, no contact of the ring element with the shaft or with the housing is caused under extreme load changes of the supercharger.

The invention allows for several embodiments and will be explained in more detail with reference to the following drawings. Hereby shows:

1 a sectional view of a conventional slide bearing assembly during use,

2 a sectional view of a first embodiment according to the invention of a bearing system of an exhaust gas turbocharger,

3 a cross-sectional and a side view of the sliding bearing assembly according to the invention,

4 a schematic view of the ring member with the inside and outside adjacent and build up during rotation hydrodynamic radial pressure curves, and

5 a sectional view of a second embodiment according to the invention of a storage system of an exhaust gas turbocharger.

1 shows a sliding bearing assembly 2 according to the prior art in an exhaust gas turbocharger 1 (please refer 2 and 5 ). The sliding bearing arrangement 2 is completely floating with a stationary housing 4 in that in known manner a housing passage 26 owns) and a rotatably arranged wave 6 , While the wave 6 has a rotational speed n1 in operation, rotates a ring element 8th at a speed of only n2. This operating condition also shows well the narrowing column 10 and the resulting displacement e1 of a housing axis 12 to a ring element axis 14 and a shaft axis 16 ,

2 shows a storage system of an exhaust gas turbocharger 1 , The wave 6 is through a thrust bearing 18 and two radial sliding bearing arrangements according to the invention 20 . 22 stored, the slide bearing arrangements 20 . 22 be through a distance bush 24 kept at a distance. Through a housing passage 26 lubricant reaches the thrust bearing 18 and slide bearing arrangements 20 . 22 , The breakthroughs 28 also allow lubricant in the slide bearing arrangements 20 . 22 arrives.

3 shows the sliding bearing assembly according to the invention 20 for an exhaust gas turbocharger 1 with a stationary bearing housing 4 and one in the ring element 8th rotatably mounted shaft 6 in a cross-sectional view and in a side view. The ring element 8th has an inner contour 29 with three inward-acting storage areas 30 . 32 . 34 and an outer contour 37 with three outward acting storage areas 31 . 33 . 35 on, each with respect to the center of the ring element 8th a in the direction of rotation of the shaft 6 have steadily decreasing radius r. Every storage area 30 . 31 ; 32 . 33 ; 34 . 35 is on a surface area 38 arranged with constant wall thickness, with each surface area 38 to the adjacent surface area 38 a transition area 36 having greater wall thickness. Consider here the possible displacement e2 of the housing axis 12 and the shaft axis 16 you can see that they are here compared to 1 is much smaller. In the slide bearing arrangement 20 There are several breakthroughs 28 , where the breakthroughs 28 allow the lubricant out of the housing passage 26 easier from outside to inside to the shaft 6 to flow. The lubricant builds up on the narrowing gaps 10 a lubricating film, causing the shaft 6 as well as the ring element 8th be self-supported.

4 shows a clockwise rotating, fully floating ring element 8th , The ring element 8th builds radial pressure curves at several points at the same time 40 on to the load through a turbine on the shaft 6 support and keep it centered. There are two internal pressure zones 42 an outer pressure zone 44 opposite and vice versa two outer pressure zones 44 an inner pressure zone 42 against the ring element 8th to stabilize.

5 shows a sectional view of a second embodiment of a storage system of an exhaust gas turbocharger. Here were the slide bearing arrangements 20 . 22 and the distance bush 24 by a combined variant with a one-piece slide bearing arrangement 46 replaced.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19539678 A1 [0005]
• DE 102012108973 A1 [0006]
• DE 10142303 A1 [0007]
• DE 102006033397 A1 [0007]

Claims (8)

Slide bearing arrangement for high rotating shafts ( 6 ) in the motor vehicle area with a stationary housing ( 4 ), in which a rotationally movable ring element ( 8th ) is provided that in turn the shaft ( 6 ) receives rotationally movable, wherein the ring element ( 8th ) to the shaft ( 6 ) directed an inner contour ( 29 ) with at least three storage areas ( 30 . 32 . 34 ), characterized in that the bearing surfaces ( 30 . 32 . 34 ) in each case with respect to the center of the ring element ( 8th ) in the direction of rotation of the shaft ( 6 ) have continuously decreasing radius r. Slide bearing arrangement according to claim 1, characterized in that the ring element ( 8th ) an outer contour ( 37 ), which the inner contour ( 29 ), so that each storage area ( 30 . 31 ; 32 . 33 ; 34 . 35 ) a surface area ( 38 ), which has a constant wall thickness and which is adjacent to the area ( 38 ) a transitional area ( 36 ) having. Slide bearing arrangement according to claims 1 or 2, characterized in that the ring element ( 8th ) is designed as a sintered part. Slide bearing arrangement according to claims 1 or 2, characterized in that the ring element ( 8th ) is designed as a continuous casting or extrusion. Slide bearing arrangement according to claims 1 or 2, characterized in that the ring element ( 8th ) is made by forming a tubular cross-section. Slide bearing arrangement according to one of the preceding claims, characterized in that the ring element ( 8th ) Breakthroughs ( 28 ), through which the lubricant between shaft ( 6 ) and the ring element ( 8th ). Bearing system with two slide bearing arrangements according to one of the preceding claims, characterized in that the two slide bearing arrangements form a one-part bearing system ( 46 ) form. Exhaust gas turbocharger with a sliding bearing arrangement according to one of the preceding claims.

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