DE102005054622A1 - Bump for moved parts relative to each other, has stacking ground of first part which has micro structure of bump and subside whereby bump is formed against direction of movement of different parts of sloped surfaces - Google Patents

Abstract

Bump has parts formed stacking ground and a lubrication solvent between the stacking ground. The stacking ground of first part (1,4) has a micro structure of bump (2,5) and subsides whereby the bump is formed against direction of movement (10) of different parts of sloped surfaces (11).

Description

The The invention relates to a bearing for relative to each other moving parts according to the preamble of the claim 1.

In the DE 102 49 818 A1 a surface of a sliding bearing is described which has recesses for a lubricant. The cup, tub, riefen- or grave-shaped recesses are 5 microns to 50 microns deep and are substantially transverse to a sliding direction. There are elevations between the recesses which form a largely flat sliding surface on their surface. The plane sliding surface prevents inadmissible point or surface loading. The transition areas between the recesses and the elevations are rounded, so that the transport of the lubricant from the recesses is improved and a floating of the bearing parts is effected.

A plain bearing surface of a piston pump after the DE 196 35 164 A1 has V-shaped lubrication grooves. Between flanks of a lubricating groove and a sliding shoe, a lubricating wedge can form. In order to obtain a good lubricating effect, the sliding bearing surface has a sufficient supporting portion, wherein the width of a lubricating groove is approximately half the size of the distance between the lubricating grooves.

According to the DE 198 36 901 C2 has a sliding bearing surface of a radial piston pump trapezoidal lubrication grooves with a depth between 1 micron and 100 microns. The number of lubrication grooves is selected such that the sum of the lubrication groove surfaces is less than 30% of the total surface area of the plain bearing surface.

A plain bearing surface of a connecting rod bearing element after the DE 197 00 339 C2 has frusto-conical lubricating oil pockets, wherein to secure a required wing portion, the pocket area is limited to 10% of the total sliding area.

In a bearing bush after the DE 199 53 576 C2 elongated lubrication pockets are provided whose longitudinal axes are perpendicular to the direction of movement of a shaft journal. The lubrication pockets have a depth between 5 microns and 20 microns and a width between 10 microns and 100 microns. In the area of the lubrication pockets, a few outlet bores for a lubricant are cut out in the bearing bush.

In the EP 0 565 742 A1 is a method for fine machining a cylinder surface of a reciprocating engine described in which with a laser regularly crossing grooves are generated, which form a lubricant reservoir. The distance of the 5 microns to 15 microns deep grooves is between 1 mm and 10 mm, so that the tread has a high proportion of flat wings.

at all solutions According to the prior art, the lubricant reservoirs are in the storage areas around macrostructures, so that in addition to containing the lubricant Wells always smooth running surfaces exist with a high percentage of support.

task The invention is a bearing for relatively moving To develop parts in which the lubricating effect is improved.

The Task is solved with a warehouse, which having the features of claim 1. Advantageous embodiments emerge from the dependent claims.

According to the invention is on a bearing part a storage area with a relief-like Microstructure provided by elevations and depressions, the surveys each having an inclined to the direction of movement of the part surface. Unlike the solutions According to the prior art, there are no flat on the surveys lying in the direction of travel wings.

The Invention causes a reduction of the friction between each other sliding bearing surfaces. By training a wedge-shaped surface structure in the micrometer range, in particular in the range of 1 .mu.m to 500 .mu.m, the Lubrication process during the relative movement of two bearing parts supported by by a taper of a lubrication gap through the inclined surface a stored in the sink lubricant by friction and Toughness forces in the Lubrication gap is promoted. additionally builds up in the lubricant pressure, so that a supporting effect of the lubricant arises. After the end of the relative movement remains the lubricant as much as possible in the sinks, resulting in resumption the relative movement reduces the static friction between the bearing parts is.

The Micro wedge structure can be obtained, for example, by methods such as X-ray lithography, Laser surface treatment or micromilling getting produced. The steadily rising wedge slopes can be in the rejuvenation direction plan, convex or concave. The rear wedge surfaces can be steep fall into the valleys or steadily sloping in or against the direction of movement fall off. The rear wedge surfaces can plan, be convex or concave. The steadily rising wedge surfaces can proceed rise from a paragraph.

The surface texture can be on level or spatially curved bearing surfaces are formed. The surface structure may be provided on a stationary or on a moving bearing part or on both interacting bearing parts. Various arrangements of the wedge-shaped elevations are possible. For example, the elevations may be formed continuously transversely to the direction of movement. Furthermore, the surveys can be designed individually freestanding. Freestanding elevations can be arranged offset in rows. During reciprocating movement of the bearing parts, the inclined surfaces can be arranged symmetrically, whereby also an offset arrangement of the symmetrical elevations can be provided. Holes for the lubricant may end in the wells. The surface structure may be made of a microporous material with lubricant passing through the micropores.

The Invention is particularly in guided in plain bearings waves and bushings applicable, as for example in internal combustion engines or cooling water pumps used by motor vehicles. The invention is also included roller bearings applicable, with a storage area for one Rolling elements and / or the rolling element itself provided with said micro wedge structure.

The Invention will be described below with reference to embodiments of plain bearings be described, showing:

1 a plan view of a structured bearing surface with lying transversely to the direction of movement wedge-shaped elevations,

2 a top view of a structured storage area with freestanding, wedge-shaped elevations,

3 a profile section through bearing parts with surveys 1 or 2 .

4 different variants of wedge-shaped elevations,

5 a plan view of a storage area with rows offset in elevations,

6 a profile section through a warehouse with a storage area after 5 .

7 a plan view of a bearing surface with lying transversely to the direction symmetrical elevations,

8th a top view of a storage area with freestanding, symmetrical elevations,

9 a profile section through bearing parts with surveys 7 or 8th .

10 a plan view of a storage area with offset in rows symmetrical elevations,

11 a profile section through a warehouse with a storage area after 10 .

12 a plan view of a bearing surface with transverse to the direction of sawtooth projections and lubricant holes in the sinks,

13 a plan view of a bearing surface with free-standing, sawtooth-shaped elevations and lubricant holes in the sinks,

14 a profile section through a warehouse with surveys 12 or 13 .

15 a plan view of a bearing surface with in-line sawtooth-shaped elevations and lubricant holes in the sinks,

16 a profile section through a warehouse with a storage area after 15 .

17 a plan view of a bearing surface with transverse to the direction symmetrical elevations and lubricant holes in the sinks,

18 a plan view of a bearing surface with freestanding, symmetrical elevations and lubricant holes in the sinks,

19 a profile section through a warehouse with surveys 17 or 18 .

20 a plan view of a bearing surface with offset in rows symmetrical elevations and lubricant holes in the sinks,

21 a profile section through a warehouse with a storage area after 20 .

22 a cross section through a radial plain bearing with sawtooth-shaped elevations in a fixed bearing bush, and

23 a cross section through a radial plain bearing with symmetrical elevations in a fixed bearing bush.

If used in the description below already introduced reference numerals are, are elements or symbols with equivalent Function or equivalent Meaning.

1 shows a plan view of a bearing part 1 the width b. On the surface is a microstructure of elevations 2 and sinks 3 educated.

In 2 is the surface of a bearing part 4 with freestanding, wedge-shaped elevations 5 and sinks 6 shown.

3 shows a profile section through a sliding bearing with a movable bearing part 7 and a fixed bearing part 1 or 4 to 1 or 2 , The bearing part 7 has a flat storage area 8th , Between the storage area 8th and the structured bearing surface of the bearing part 1 respectively. 4 there is a lubricant 9 , In the direction of movement 10 of the storage part 7 are the surveys 2 . 5 equidistant at a distance a. The surveys 2 . 5 point to the direction of movement 10 inclined surfaces on, in profile as rising leading edges 11 appear. The surveys 2 . 5 rise to a maximum value h _max and fall on trailing edges 12 abruptly to the level of sinks 3 . 6 from. The valleys 3 . 6 are flat and parallel to the storage area 8th educated. Transverse to the direction of movement 10 own the surveys 5 a distance c.

Between the inclined surfaces of the surveys 2 . 5 and the storage area 8th exist in the direction of movement 10 Tapers. During movement of the bearing part 7 in the direction of movement 10 becomes lubricant 9 pressed into the tapers, so that builds up a pressure on the bearing part 7 a supporting effect and the bearing part 7 at a distance d to the bearing part 1 respectively. 4 holds. The distances a, c, d and the height h _max are in the micrometer range preferably in the range of 1 to 500 .mu.m, particularly preferably between 200 and 500 .mu.m.

In the 4.1 - 4.18 are possible profile forms of surveys 2 . 5 shown.

The leading edges 11 the surveys 2 . 5 to 4.1 - 4.7 rise linearly with a pitch angle α of about 30 °. Preferably, the angle is in the range of 30 ° to 45 °. The leading edges 11 the surveys 2 . 5 after the 4.4 - 4.7 start from the valley 3 . 6 starting with one paragraph each 13 , The 4.8 - 4.11 and 4.18 show variants with convex leading edges 11 , The leading edges 11 the surveys 2 . 5 after the 4.12 - 4.17 are concave.

The trailing edges 12 the surveys 2 . 5 after the 4.1 . 4.4 . 4.8 and 4.12 fall vertically into the plane of the valleys 2 . 6 , The trailing edge 12 the surveys 2 . 5 to 4.2 and 4.15 fall linearly in a slope with the angle β in the plane of the sink 2 . 6 , wherein the pitch angle α of the leading edge 11 is less than the pitch angle β of the trailing edge 12 , The linear trailing edges 12 to 4.3 . 4.5 . 4.9 and 4.13 each undercut the elevation 2 . 5 by a small amount. According to 4.6 . 4.10 and 4.14 are the undercut trailing edges 12 each concave. The trailing edges 12 to 4.7 . 4.11 and 4.16 fall obliquely into the depression 2 . 6 and are convex. The trailing edges 12 the surveys 2 . 5 after the 4.17 and 4.18 are concave and fall off faster than the respective leading edges 11 ,

5 and 6 show a plan view of a bearing surface and a profile section through a bearing with in rows 14.1 - 14.5 , offset surveys 5 and sinks 6 with a sawtooth-shaped profile 4.1 , The in the direction of movement 10 equally spaced surveys 5 of the ranks 14.1 . 14.3 . 14.5 are to the surveys 5 in the rows 14.2 . 14.4 180 ° out of phase. The valleys 6 lie in the rows 14 , where the width of the surveys 5 and the sinks 6 correspond to the row width e. Between the rows 14 there is no distance.

The 7 - 9 show a variant with symmetrical elevations 15 on a fixed bearing part 4 , The movable bearing part 7 is stored reciprocally, which is indicated by a double arrow 10 is symbolized. Depending on the direction of movement 10 one of the flanks acts 16 . 17 as a leading edge 11 with the effects described above.

The variant after the 10 . 11 shows symmetrical elevations in plan view and in profile 15 how to the 7 - 9 described. The surveys 15 are in parallel rows 14.1 - 14.5 arranged, with the tips of the surveys 15 adjacent rows 14 in the direction of movement 10 are offset by 180 ° to each other. As with the variant after the 5 and 6 lie the rows 14 without a gap.

The plain bearings after the 12 - 14 own on the fixed bearing part 1 respectively. 4 the to the 1 - 3 described micro-profiles. In the valleys 6 ends lubricant bores 18 , For freestanding, in rows 14.1 - 14.3 arranged surveys 5 , as in 13 shown, are the holes 18 each in the middle of the row.

The sliding bearing variant after the 15 . 16 corresponds in terms of microstructure in the 5 and 6 shown variant. In the valleys 6 ends lubricant bores 18 that like the surveys 5 and sinks 6 checkerboard pattern on the surface of the bearing part 4 lie spread.

In the 17 - 19 is a warehouse with one Microstructure after the 7 - 9 shown. Also in this variant ends in the sinks 6 lubricant holes 18 in the case of freestanding surveys 15 the flanks 16 . 17 in the direction of movement 10 are each preceded by.

The 20 and 21 show a variant with a microstructure according to the 10 and 11 , In a staggered arrangement of the symmetrical elevations 15 lie the outlet openings of lubricant holes 18 also offset like a checkerboard on the surface of the bearing part 4 ,

In the 22 and 23 are cross sections through circular cylindrical radial plain bearings with sawtooth and symmetrical elevations 5 . 15 in a fixed bushing 19 . 20 shown. According to 22 are the leading edges 11 the sawtooth-shaped elevations 5 circumferentially according to the direction of rotation 21 a shaft to be stored 22 . 23 arranged. When the wave 23 in both directions 21 is rotatable, then, as in 23 shown a microstructure with symmetrical elevations 15 provided, whose flanks 16 . 17 in both directions of rotation a bearing pressure in the lubricant 9 produce.

List of used reference numeral

1

bearing part

2

survey

3

depression

4

bearing part

5

survey

6

depression

7

bearing part

8th

storage area

9

lubricant

10

movement direction

11

leading edge

12

trailing edge

13

paragraph

14

line

15

survey

16 17

flank

18

lubricant bore

19 20

bearing bush

21

direction of rotation

22 23

wave

b

width

a

distance

c, d

distance

h _max

height

Claims (9)

Bearing for relatively moving parts, with bearing surfaces formed on the parts, and with a lubricant between the bearing surfaces, characterized in that at least one bearing surface of a first part ( 1 . 4 . 19 . 20 ) a microstructure of surveys ( 2 . 5 . 15 ) and sinks ( 3 . 6 ), whereas at the surveys ( 2 . 5 . 15 ) against the direction of movement ( 10 ) of the other part ( 7 ) inclined surfaces ( 11 . 16 . 17 ) are formed. Bearing according to claim 1, characterized in that in a sliding bearing a sliding surface has a micro wedge profile. Bearing according to claim 1, characterized in that the elevations ( 2 . 5 . 15 ) and sinks ( 3 . 6 ) in rows ( 14 ) transverse to the direction of movement ( 10 ) are arranged. Bearing according to claim 1, characterized in that the elevations ( 5 . 15 ) are arranged freestanding in a grid. Bearing according to claim 1, characterized in that the elevations ( 5 . 15 ) in the direction of movement ( 10 ) rows ( 14 ) are arranged free-standing and offset from one another. Bearing according to claim 1, characterized in that at the elevations ( 15 ) on both sides in the direction of movement ( 10 ) inclined surfaces ( 16 . 17 ) are formed. Bearing according to claim 1, characterized in that the inclined surfaces ( 11 . 16 . 17 ) are concave. Bearing according to claim 1, characterized in that the inclined surfaces ( 11 . 16 . 17 ) are convex. Bearing according to claim 1, characterized in that in the wells ( 3 . 6 ) Lubricant channels ( 18 ) end up.