WO2017157378A1

WO2017157378A1 - Anti-friction bearing, eccentric drive having an anti-friction bearing of this type, and radial piston pump and use thereof

Info

Publication number: WO2017157378A1
Application number: PCT/DE2017/100151
Authority: WO
Inventors: Steffen BREHM; Jürgen Klonus; Marcus Gerngross; Thomas Kandler; Richard Frisch; Christopher HALUF; Jan KRÄMER; Markus Baier; Andreas Kohl
Original assignee: Schaeffler Technologies AG & Co. KG
Priority date: 2016-03-17
Filing date: 2017-02-27
Publication date: 2017-09-21
Also published as: DE102016204458B4; DE102016204458A1

Abstract

The invention relates to an anti-friction bearing (4', 4'') which has at least one outer sleeve (9) with an outer casing surface (9') and a running surface (9'') which faces away from the outer casing surface (9'), and with a number of rolling bodies (5) which are received in the outer sleeve (9) and are arranged in contact with the running surface (9''), wherein the outer sleeve (9) has a first end (10) and a second end (11). The outer casing surface (9') of the outer sleeve (9) is of convex configuration in such a way that an outer diameter of the outer sleeve (9), starting from the first end (10) of the outer sleeve (9), increases continuously at least from the beginning of the running surface (9'') up to a maximum outer diameter (D) and, starting from the maximum outer diameter (D), decreases continuously in the direction of the second end (11) at least as far as the end of the running surface (9'').

Description

Rolling, eccentric drive with such a rolling bearing and radial piston pump and their use

The invention relates to a roller bearing, which has at least one outer sleeve with an outer lateral surface and a running surface facing away from the outer lateral surface, and with a number of received in the outer sleeve rolling elements, which are arranged in contact with the tread, wherein the outer sleeve has a first end and a second end. The invention further relates to an eccentric drive, in particular for a radial piston pump, comprising a shaft rotatable about its longitudinal axis and a radial rolling bearing arranged on the shaft, the radial rolling bearing comprising at least one outer sleeve facing away from the shaft and a number of rolling elements accommodated in the outer sleeve, wherein the radial roller bearing is arranged either eccentrically to the longitudinal axis of the shaft on the shaft or is arranged on an eccentric ring which is rotatably connected to the shaft. Finally, the invention relates to a radial piston pump comprising at least one pump piston and such an eccentric drive, as well as their use.

Rolling, eccentric and radial piston pumps of the type mentioned are already known.

For example, WO 2008/1 19596 A2 discloses a radial roller bearing with an outer sleeve in the form of a sleeve for an eccentric drive, which is used in particular in radial piston pumps. The radial rolling bearing is arranged eccentrically to the longitudinal axis of a pump shaft on the pump shaft.

DE 19839430 A1 describes a radial piston pump with a rotating pump shaft, a rotatably mounted eccentric ring and a needle bearing and a pump piston. US 2002/1 10301 A discloses a rolling bearing with an outer sleeve and needle-shaped rolling elements, wherein the rolling elements are in contact with a convexly formed running surface of the outer sleeve. With regard to the known radial piston pumps, it has proven to be problematic that in the area of contact between pump piston and outer sleeve of the radial roller bearing due to an axial thrust occurring a significant wear occurs, which limits the life of the radial piston pump.

It has been shown that the shape of the outer sleeve in known rolling bearings, which are used for radial piston pumps, due to a production-related out-of-roundness is not cylindrical, but is slightly incidental and concave. There arises at two points a contact between the pump piston and the outer diameter of the outer sleeve, which results in an axial positive guidance of the respective pump piston on the outer sleeve. Due to this two-point contact, in the presence of system-related axial forces, on the one hand, due to the resulting axial thrust, unfavorable force is introduced into the rolling bearing, which leads to a reduced service life and increased axial wear of the bearing arrangement. On the other hand, there is a, in the direction of the longitudinal axis of the shaft of the radial piston pump pronounced tilting of the pump piston, which causes an increased and accelerated wear of the seals in the system-side guidance of the pump piston. As a result of worn seals, the proportion of small particles increases in the reciprocating system and it can, for example, when used in a brake system of a motor vehicle to an entry of brake fluid in the bearing assembly. This further reduces the service life of the radial piston pump.

It is therefore an object of the invention to provide a rolling bearing and an eccentric drive formed therewith, which permit a significant extension of the service life of a radial piston pump, and to provide a radial piston pump formed therewith and its preferred use.

The object is with regard to the rolling bearing, which has at least one outer sleeve with an outer lateral surface and a running surface facing away from the outer lateral surface, and with a number of received in the outer sleeve rolling elements, which are arranged in contact with the tread, wherein the outer sleeve has a first end and has a second end, achieved in that the lateral surface of the outer sleeve is formed convex such that an outer diameter of the outer sleeve starting from the first end of the outer sleeve at least from the beginning of the tread steadily increases up to a maximum outer diameter and starting from the maximum outer diameter in the direction of the second end at least until the end of the tread steadily decreases.

In this case, a "start" and an "end" of the tread-seen in longitudinal section through the outer sleeve and the rolling elements-is understood to mean a limit of the tread assigned to the first end or the second end of the outer sleeve. Accordingly, at least in the region of the outer lateral surface of the outer sleeve, which is arranged vertically above or below the running surface, is on either side of the maximum outer diameter D, a sloping course, i. a steady decrease of the outer diameter in the direction of the first end as well as the second end, present. It is essential, however, that the outer circumferential surface in the region of the first end and the second end, i. in areas which are arranged in the sectional view next to or offset from the tread, has no outer diameter which is greater than the maximum outer diameter D.

Through this convex shape of the outer circumferential surface of the outer sleeve of the rolling bearing, a point contact between the outer sleeve and the respective pump piston results in a radial piston pump, in which the rolling bearing is installed. These changed contact conditions cause the at least one pump piston exclusively in the presence of axial forces performs a radial lifting movement. Thus, on the one hand, the life of the bearing assembly is increased, reduces the wear by axial thrust and further minimizes the wear of the seals in the leadership of the pump piston.

The inner circumferential surface of the outer sleeve may, in addition to the invention, for example, from the first end to the second end, at least in the region of the raceway of the rolling elements, constant inner diameter. If crowned rolling elements, in particular convex needles, are provided, then the inner circumferential surface, at least in the region of the raceway of the rolling elements, can likewise be adapted to the crowning of the needles or follow the profile of the convex shape of the outer lateral surface, so that the wall thickness is constant , The outer sleeve of the rolling bearing is formed in particular by pulling. The convex or spherical shape of the outer surface of the outer sleeve is achieved by already known manufacturing technologies, here a deep drawing and crimping of the outer sleeve. In this case, a stamp is inserted into the outer sleeve and this formed accordingly. This results in an optimized roughness of the surface of the raceway of the outer sleeve, which improves the rolling behavior of the rolling elements as a result. Alternatively, the outer sleeve of the rolling bearing can obtain its shape by a swaging process or by a cutting process.

Wall thickness differences of from 5 to 25 μm, which have been produced in particular by a chipless method, have proven to be particularly advantageous in order to obtain the crowning of the convex shape required with regard to improved functioning of the bearing. The wall thickness differences are to be understood in the sectional view of the bearing as in the radial direction different distances of the inner and outer lateral surfaces (-Iinie) to the axis of rotation. Preferably, the lateral surface of the outer sleeve, at least in the region of the running surface (9 ^" ), has a course which corresponds to a parabola of the formula

y (x) = ax ²

where a takes on values in the range of 1.7 * 10 ^-5 and 2.0 * 10 ^-3 and a vertex of the parabola is at the maximum outer diameter D. Such a course has proved particularly durable in use and reduces wear.

The maximum outer diameter of the outer sleeve extends in particular on a circumferential line of the outer sleeve, which is arranged concentrically to a virtual line which extends through the centers of gravity of the rolling elements. As a result, an optimal load transfer is given in the rolling elements. In a preferred embodiment of the rolling bearing a rolling bearing cage for receiving the rolling elements is also available. This can be designed as a plastic cage or metal cage. But full complement variants of the rolling bearing are possible. The rolling elements of the rolling bearing are preferably formed like a needle, so that a needle bearing is formed. However, other embodiments of the rolling bearing according to the invention comprising for example spherical, conical or cylindrical rolling elements instead of needle-shaped rolling elements are possible. Variants of the rolling bearing having at least one inner ring, which is arranged between the shaft or a shaft portion on the one hand and the rolling elements on the other hand or between the eccentric ring on the one hand and the rolling elements on the other hand, are considered to be inventive. It has proven useful if at the first end and / or the second end of the outer sleeve, a board is formed, which points in the direction of the rolling elements. For this purpose, the end of the outer sleeve is angled at approximately 90 ° and forms a leading edge for rolling elements or Wälzkörperkäfig. Such a board limits the path that the rolling elements, if appropriate also a cage, can travel between the first end and the second end of the outer sleeve.

Furthermore, it has proven useful if at the first end or the second end of the outer sleeve, a board is formed which faces in the direction of the rolling elements, and that the outer sleeve is formed as a sleeve, wherein the outer sleeve at its, the board opposite end a can bottom is closed. Such variants allow a particularly good sealing of the rolling bearing against

Lubricant loss.

The object is for the eccentric drive comprising a shaft rotatable about its longitudinal axis and a radial rolling bearing arranged on the shaft, the radial rolling bearing comprising at least one outer sleeve facing away from the shaft and a number of rolling elements received in the outer sleeve, the radial rolling bearing being either eccentric to the longitudinal axis the wave is arranged on the shaft or on an eccentric ring is arranged, which is rotatably connected to the shaft, achieved in that a rolling bearing according to the invention is provided as a radial rolling bearing. Again, the advantages already mentioned above for the rolling bearing according to the invention apply.

The object is achieved for the radial piston pump characterized in that it comprises an eccentric drive according to the invention and at least one pump piston, wherein the at least one pump piston has a contact surface which is in point contact with the maximum outer diameter of the outer sleeve of the radial roller bearing. The contact surface of the pump piston can be flat or spherical.

The radial piston pump according to the invention is improved in terms of their susceptibility to axial thrust. Along with this occurs a reduction in wear and an increase in the life. This is achieved essentially by the convex shape of the lateral surface of the outer sleeve of the radial roller bearing. The eccentric drive transforms a rotational movement of the shaft into a radial lifting movement of the pump pistons which are in contact with the outer lateral surface of the outer sleeve of the roller bearing or radial roller bearing. The point contact between pump piston and outer sleeve does not permit any resulting forces in the axial direction and therefore leads to a purely radial lifting movement of the pump pistons. A load distribution on the rolling elements is ideally pronounced in a point contact according to the invention, while it comes in the previously occurring two-point contact in conjunction with axial thrust to an inhomogeneous load distribution, which leads to increased Axialverschleiß and tilted barrel.

The outer sleeve is formed sufficiently dimensionally stable so that the outer circumferential surface is not deformed during operation of the radial piston pump and in turn leads to a deterioration of the wear behavior. Case steel has proven to be the material for the outer sleeve. In particular, the outer sleeve is dimensionally stable with a wall thickness in the range of at least 1 mm to about 2.5 mm. The use of a radial piston pump according to the invention for generating a hydraulic pressure in a brake system of a motor vehicle has proven itself.

FIGS. 1 to 7 are intended to explain the state of the art and the invention in detail. So shows:

1 shows a radial piston pump with a rolling bearing according to the prior art in the sectional view; FIG. 2 shows the radial piston pump according to FIG. 1 with ideal viewing in half section; FIG. 3 shows the radial piston pump according to FIG. 1 when viewed in real-time in half section; 4 shows a radial piston pump according to the invention in half section;

5 shows an eccentric drive according to the invention with a rolling bearing according to the invention in a sectional view;

6 shows the radial piston pump according to FIG 4 in an enlarged view in half section; and

7 shows a further inventive radial piston pump in a sectional view.

1 shows a radial piston pump 1 with a rolling bearing 4 according to the prior art in the sectional view, wherein a shaft 2 is provided with a longitudinal axis 3, about which the shaft 2 is rotatable. On the shaft 2 and a shaft portion 2a, an eccentric ring 7 is arranged, which is enclosed by the rolling bearing 4 in the form of a needle bearing. The rolling bearing 4 includes an outer sleeve 9 having an outer lateral surface 9 ^'and one of the outer lateral surface ^9' facing away from the tread 9. ^"It also is a number of captured in the outer sleeve 9 rolling elements 5, which in contact with the tread ^9" are arranged, available. The rolling elements 5 are guided by a roller bearing cage 6. The outer sleeve 9 has a first end 10 with a shelf 9a and a second end 1 1 with a further shelf 9b. Within the further shelf 9b is located to fix the position of the rolling bearing cage 6, a disc. 8 In contact with the outer circumferential surface 9 ^'of the outer sleeve 9 pump piston 12, 13 are arranged, which execute a lifting movement of the shaft 2 about the longitudinal axis 3. In this case, further pump pistons, which are not visible in this view, with the outer circumferential surface 9 ^'of the outer sleeve 9 are in contact. The eccentric ring 7 rotating with the shaft 2 or the shaft section 2a transforms the rotational movement of the shaft 2 into a radial lifting movement of the contact surfaces 12a, 13a of the pump pistons 12, 13 which are in contact with the outer jacket surface 9 ^' .

2 shows the known radial piston pump 1 according to FIG 1 with ideal viewing in half section. Here, an ideal cylindrical shape of the outer sleeve 9 and the outer circumferential surface 9 ^'is assumed. Here, the contact surfaces 12a, 13a of the pump piston 12, 13 (see FIG. 1) are in contact with the outer jacket surface 9 ^'of the outer sleeve 9, a line contact being formed for this ideal case. It is also the theoretical course of the introduction of force into the rolling elements 5 is shown. Occurs during operation of the radial piston pump 1 in the contact area wear and consequently an axial thrust S, so acts a radial force Fmd and an axial force Fax. The resulting force Fres = V (Frad ² + Fax ² ) leads to a further uneven wear in the region of the outer circumferential surface 9 ^'of the outer sleeve 9, as well as wear in the region of the contact surfaces 12a, 13a of the pump piston 12, 13 and their guidance and sealing due to tilting.

FIG. 3 now shows the radial piston pump 1 according to FIG. 1 when viewed in real-time in half section. It is not assumed here of an ideal cylindrical shape of the outer sleeve 9 and the outer circumferential surface 9 ^' . Due to a production-related out-of-roundness, the outer sleeve 9 is generally not ideally cylindrical, but slightly incidental and concave. There arises in two places a contact between the respective pump piston 13 and the outer circumferential surface 9 ^'of the outer sleeve 9, which results in an axial positive guidance of the respective pump piston 12, 13 on the outer sleeve 9. Due to this two-point contact occurs in the presence of systemic axial forces Fax on the one hand due to the resulting axial thrust S unfavorable force into the rolling bearing 4, which leads to a reduced life and increased axial wear of the bearing assembly. On the other hand, it comes to one, in the direction of the longitudinal axis 3 of the shaft 2 of the Radial piston pump 1 pronounced tilting of the respective pump piston 12, 13, which causes an increased and accelerated wear of the seals in the system-side guidance of the pump piston 12, 13. As a result of worn seals, the proportion of small particles in the reciprocating system increases and, for example, when used in a brake system of a motor vehicle, an entry of brake fluid into the rolling bearing 4 can occur. This reduces the life of the radial piston pump 1 even further.

Occurs during operation of the radial piston pump 1, an axial thrust S, so acts as already shown in FIG 2, a radial force Fmd and an axial force Fax. The resulting force Fres = V (Frad ² + Fax ² ) leads to wear in the region of the outer circumferential surface 9 ^'of the outer sleeve 9 and in the region of the contact surfaces 12a, 13a of the pump piston 12, 13 and their guidance and sealing. It is also the uneven and therefore unfavorable course of the introduction of force into the rolling elements 5 shown.

4 now shows a first radial piston pump 1 ^' according to the invention with a rolling bearing 4 ^' according to the invention or radial rolling bearing in half section. The same reference numerals as in FIGS. 1 to 3 designate the same elements. Tread, the rolling bearing 4 ^', the outer sleeve 9 with the outer lateral surface ^9' and one of the outer lateral surface 9 ^'facing away 9 ^"on. There is a number of captured in the outer sleeve 9, needle-shaped rolling elements 5 is provided in contact with the tread ^9" are arranged and guided by a roller bearing cage 6. The outer sleeve 9 has a first end 10 and a second end 1 1, wherein at the first end 10 and the second end 1 1 of the outer sleeve 9 each have a shelf 9 a, 9 b is formed, which points in the direction of the rolling elements 5. The lateral surface 9 ^'of the outer sleeve 9 is convex such that an outer diameter of the outer sleeve 9, starting from the first end 10 of the outer sleeve 9 steadily increases up to a maximum outer diameter D and starting from the maximum outer diameter D in the direction of the second end 1 1 decreases steadily , Conversely, it is of course also possible that an outer diameter of the outer sleeve 9, starting from the second end 1 1 of the outer sleeve 9 steadily increases up to a maximum outer diameter D and starting from the maximum outer diameter D in the direction of the first end 10 decreases steadily. In this case, the steady increase in the outer diameter of the outer sleeve 9 up to the maximum outer diameter D can be relationship as the steady decrease of the outer diameter of the outer sleeve 9 only be ^"from the maximum outer diameter D in the region of the tread. 9 important here, however, that the outer lateral surface 9 ^'in the area of the first end 10 and the second end 1 1, ie in the areas which are arranged in the sectional view next to or offset from the tread 9 ^"has no outer diameter which is greater than the maximum outer diameter D. This ensures the desired point contact between outer sleeve 9 and pump piston 12, 13.

The maximum outer diameter D of the outer sleeve 9 extends here on a circumferential line of the outer sleeve 9, which is arranged concentrically to a virtual line which extends through the centers of gravity of the needle-shaped rolling elements 5. Between the pump piston 12, 13 or the contact surfaces 12a, 1 3a (see FIG. 1) and the outer lateral surface 9 ^' , a punctiform contact is formed. The point contact allows no resulting forces in the axial direction and therefore leads to a purely radial lifting movement of the pump piston 12, 13. It applies here: Fres- Frad Qualitatively also the load distribution on the rolling elements 5 was drawn, which is ideally designed for such a point contact ,

The result is a straight stroke of the pump piston 12, 13 without any tilting or damage to the guides and seals of the pump piston 12, 13 and due to the minimized punctiform contact surface, a particularly low wear in the contact area between the pump piston 12, 13 and outer sleeve. 9

5 shows an eccentric drive 14 according to the invention with a rolling bearing 4 ^' according to the invention in a sectional view. The rolling bearing 4 ^' used here corresponds to that used in FIG. The same reference numerals as in FIG. 4 or FIG. 1 designate the same elements. Clearly, the convex shape of the outer sleeve 9 can be seen, wherein the maximum outer diameter D of the outer sleeve 9 is noted. Starting from the circumferential line of the outer sleeve 9, which is located at the maximum outer diameter D, the outer diameter of the outer sleeve 9 in the direction of the first end 10 and the second end 1 1 decreases steadily.

6 shows the radial piston pump 1 ^' according to FIG. 4 in an enlarged view in half section. The same reference numerals as in FIG. 4 or FIG. 5 designate the same elements. In this view, the contact surface 13a of the pump piston 13 can be seen. NEN, which is in point contact with the outer sleeve 9. The outer sleeve 9 must be formed sufficiently stable deformation, so that the outer surface 9 ^' is not deformed during operation of the radial piston pump 1 ^' and in turn leads to a deterioration of the wear behavior.

7 shows a further radial piston pump 1 ^" according to the invention in the cross-sectional view The same reference numerals designate the same elements as in FIG 6 or FIG 1. There is a roller bearing 4 ^" according to the invention which has an outer sleeve 9 with an outer jacket surface 9 ^' and one of the outer jacket surface 9 ^'facing away running surface che 9 ^"has. at the first end 10 of the outer sleeve 9, a board 9a is formed, pointing towards the rolling bodies. 5 the outer sleeve 9 is formed here as a sleeve, wherein the outer sleeve 9 at its the board 9a The bush bottom 9c is braced against the shaft 2 or the shaft section 2a via a lug 9d The rolling bearing 4 ^" is here directly on the shaft section 2a, which is eccentric to the longitudinal axis 3 of the shaft 2 is arranged. The on-board 9a encloses a disc 8 which acts also as a seal and the roller bearing 4 ^"protects against loss of lubricant. The lateral surface 9 ^'of the outer sleeve 9 is convexly formed such that an outer diameter of the outer sleeve 9 starting from the first end 10 of the outer sleeve 9 steadily increases up to a maximum outer diameter D and steadily decreases starting from the maximum outer diameter D in the direction of the second end 1 1. For this embodiment too, the outer sleeve 9 must be designed sufficiently stable in deformation, so that the outer circumferential surface 9 ^' does not deformed during operation of the radial piston pump 1 ^" and in turn leads to a deterioration of the wear behavior.

Further embodiments of the rolling bearing according to the invention comprising, for example, spherical, conical or cylindrical rolling bodies instead of needle-shaped rolling bodies are possible. Variants of the rolling bearing according to the invention, which have at least one inner ring which is arranged between the shaft 2 or the shaft portion 2a on the one hand and the rolling elements 5 on the other hand or between the eccentric ring 7 on the one hand and the rolling elements 5 on the other hand, can be used within the meaning of the present invention. LIST OF REFERENCE NUMBERS

1, 1 ^' , 1 ^" radial piston pump

wave

a shaft section

longitudinal axis

, 4 ^' , 4 ^" bearings

5 rolling elements

Rolling bearing cage

7 eccentric ring

8 disc

9 outer sleeve

9 ^' outer lateral surface

9 ^" tread

9a board

9b board

9c can bottom

9d nose

10 first end of the outer sleeve

1 1 second end of the outer sleeve

12, 13 pump piston

12a, 13a contact surface

14 eccentric drive

D maximum outer diameter

S axial thrust

Claims

claims

1 . Rolling (4 ^' , 4 ^" ), the at least one outer sleeve (9) with an outer

Mantle surface (9 ^' ) and one of the outer circumferential surface (9 ^' ) facing away from running surface (9 ^" ), and having a number of in the outer sleeve (9) received rolling elements (5), which are arranged in contact with the running surface (9 ^" ) wherein the outer sleeve (9) has a first end (10) and a second end (1 1), characterized

that the outer lateral surface (9 ^' ) of the outer sleeve (9) is convex such that an outer diameter of the outer sleeve (9), starting from the first end (10) of the outer sleeve (9) at least from the beginning of the tread (9 ^" ) steadily increases until to a maximum outer diameter (D) and starting from the maximum outer diameter (D) in the direction of the second end (1 1) at least until the end of the tread (9 ^" ) steadily decreases.

2. Rolling bearing (4 ^' , 4 ^" ) according to claim 1, characterized in that

that the outer lateral surface (9 ^' ) of the outer sleeve (9) has a course, at least in the region of the running surface (9 ^" ), of a parabola of the formula

y (x) = ax ²

where a takes on values in the range of 1.7 * 10 ^{~ 5} and 2.0 * 10 ^{~ 3} and a vertex of the parabola is at the maximum outer diameter (D).

3. rolling bearing (4 ^' , 4 ^" ) according to claim 1 or claim 2, characterized in that the maximum outer diameter (D) of the outer sleeve (9) on a circumferential line of the outer sleeve (9) extends concentrically to a virtual line is arranged, which passes through the centers of gravity of the rolling elements (5).

4. rolling bearing (4 ^' , 4 ^" ) according to one of claims 1 to 3, characterized in that further comprises a roller bearing cage (6) for receiving the rolling elements (5) is present.

5. Rolling bearing (4 ^' , 4 ^" ) according to one of claims 1 to 4, characterized in that the rolling bodies (5) are formed in a needle-shaped.

6. rolling bearing (4 ^' , 4 ^" ) according to one of claims 1 to 5, characterized in that at the first end (10) and / or the second end (1 1) of the outer sleeve (9) has a shelf (9a, 9b ) is formed, which points in the direction of the rolling elements (5).

7. rolling bearing (4 ^' , 4 ^" ) according to one of claims 1 to 6, characterized in that at the first end (10) or the second end (1 1) of the outer sleeve (9) a board (9 a, 9 b) is formed is that points in the direction of the rolling elements (5), and that the outer sleeve (9) is formed as a sleeve, wherein the outer sleeve (9) at its the board (9a, 9b) opposite end with a bush bottom (9c) is closed ,

8. eccentric drive (14), in particular for a radial piston pump (1 ^' , 1 ^" ), comprising a about the longitudinal axis (3) rotatable shaft (2) and one on the shaft (2) arranged radial roller bearing, wherein the radial roller bearing at least one of the shaft (2) facing away from the outer sleeve (9) and a number of in the outer sleeve (9) received rolling elements (5), wherein the radial rolling bearing either on an eccentric ring (7) which is rotatably connected to the shaft (2) is arranged, or is arranged eccentrically to the longitudinal axis (3) of the shaft (2) on the shaft (2),

characterized in that a rolling bearing (4 ^' , 4 ^" ) according to one of claims 1 to 7 is present as a radial roller bearing.

9. Radial piston pump (1 ^' , 1 ^" ), comprising an eccentric drive (14) according to claim 8 and at least one pump piston (12, 13), wherein the at least one pump piston (12, 13) has a contact surface (12a, 13a), the is in a point contact with the maximum outer diameter (D) of the outer sleeve (9) of the radial roller bearing. Use of a radial piston pump (1 ^' , 1 ^" ) according to claim 9 for generating a hydraulic pressure in a brake system of a motor vehicle.