BEARING ARRANGEMENT FOR RADIAL PISTON UNITS

Abstract

A hydrostatic radial piston unit of the cam-lobe type of construction having a non-rotary, stationary shaft defining a rotational axis of the hydrostatic radial piston unit. A non-rotary, stationary casing houses the shaft in a torque proof connection. A rotary casing is provided which is rotary around the rotational axis. A pair of roller bearings supports the rotary casing in a rotatable manner against the stationary casing, wherein the pair of roller bearings is arranged in an axial overlapping area in which the stationary casing and the rotary casing overlap.

Claims

1. A hydrostatic radial piston unit of the cam-lobe type of construction comprising: a non-rotary, stationary shaft defining a rotational axis of the hydrostatic radial piston unit; a non-rotary, stationary casing housing the shaft in a torque proof connection; a cylinder block arranged stationary in torque-proof connection with the stationary shaft on a front end portion of the stationary shaft protruding from the stationary casing; a rotary casing which is rotary around the rotational axis and surrounds the cylinder block at the protruding front end of the stationary shaft; exact two roller bearings which are arranged as a pair of roller bearings next to or in a close proximity to each other, wherein the pair of roller bearings rotary supports the rotary casing against the stationary casing, and is disposed in the axial area adjacent to the cylinder block side facing toward the stationary casing, surrounds at least partially a hollow shaft part of a rotary distributor, and is arranged in an axial overlapping area in which the stationary casing and the rotary casing overlap.

2. The hydrostatic radial piston unit according to claim 1, wherein the rotary distributor comprises a disc-shaped part being in torque proof connection with the rotary casing, wherein the pair of roller bearings is arranged radially outside of the hollow shaft part of the rotary distributor.

3. The hydrostatic radial piston unit according to claim 1, wherein the stationary casing comprises an extension extending in axial direction beyond a sealing plane into the volume of the rotary casing and radially between the hollow shaft part of the rotary distributor is provided to accommodate the inner shells of the pair of roller bearings.

4. The hydrostatic radial piston unit according to claimn 3, wherein the extension is provided as additional part and is attached to the stationary casing.

5. The hydrostatic radial piston unit according to claim 1, wherein the pair of roller bearings is positioned basically at the same axial position as a flange, a sprocket or a similar torque transmission device at an outer circumferential surface of the rotary casing.

6. The hydrostatic radial piston unit according to claim 1, comprising a stationary multiple-speed-control-valve switchable between a first position in which all cylinder bores of a stationary cylinder block can be supplied with hydraulic fluid under high pressure from a high pressure inlet of the hydrostatic radial piston unit and a second position in which only a portion of the cylinder bores is supplied with fluid under high pressure and pairs of cylinder bores are hydraulically short-circuited.

7. The hydrostatic radial piston unit according to claim 6, wherein the stationary multiple-speed-control-valve is arranged in an axial bore in the stationary shaft, wherein the axial bore is preferably coaxially arranged with the longitudinal axis.

8. The hydrostatic radial piston unit according to claim 6, wherein the multiple-speed-control-valve is a two-speed-control-valve or a three-speed-control-valve.

9. The hydrostatic radial piston unit according to claim 1, comprising a park brake mechanism with brake discs located in the overlapping area between the stationary casing and the rotary casing and fixed alternatively to the stationary casing and the rotary casing, wherein the park brake mechanism comprises a blocking position in which the brake discs are pressed against each other and the rotary casing is fixed in relation to the stationary casing and an open position in which the brake discs are not pressed against each other and the rotary casing can rotate in the relation to the stationary casing.

10. The hydrostatic radial piston unit according to claim 9, wherein the pre-tensioning force of a disc spring can be transmitted to the brake discs by means of a disc-shaped brake piston and by means of brake pins extending in an axial direction between the brake piston and the brake discs.

11. The hydrostatic radial piston unit according to claim 9, wherein the at least one brake pin comprises a portion with higher diameter at the end facing towards the brake piston.

12. The hydrostatic radial piston unit according to claim 11, wherein the park brake mechanism can be switched into its open position by supplying a hydraulic pressure to a pressure chamber sealed by a front end and a rear end of the at least one brake pin, such that the brake pin is forced towards the brake piston and forces the brake piston to compress the disc spring, therewith releasing the compressing force from the brake discs.

13. The hydrostatic radial piston unit according to claim 10, wherein the park brake mechanism can be switched into its open position by supplying a hydraulic pressure acting on a release surface of the disc-shaped brake piston which generates a counterforce to the pre-tensioning force of the disc spring.

14. The hydrostatic radial piston unit according to claim 1, wherein a cam lobe surface is integrally formed with the rotary casing.

15. The hydrostatic radial piston unit according to claim 1, wherein distributor springs and/or distributor pistons are received in axially oriented holes in the rotary casing or in the disc-shaped part to urge the rotary distributor against a lateral surface of the cylinder block.

16. The hydrostatic radial piston unit according to claim 15, wherein the axially oriented holes receiving the distributor springs and/or the distributor pistons are arranged in the recesses of the cam-lobe-surface in the rotary casing or in an elevation formed in the disc-shaped part of the distributor.

17. The hydrostatic radial piston unit according to claim 6, wherein the cylinder block comprises more than one row of cylinder bores and radially reciprocating working pistons which are arranged in circumferential direction adjacent or staggered to each other and can interact with the cam-lobe surface.

18. The hydrostatic radial piston unit according to claim 1, wherein a second cylinder block, whose working pistons interact with the cam-lobe surface is arranged parallel to the first cylinder block on the stationary shaft.

19. The hydrostatic radial piston unit according to claim 18, wherein the numbers of cylinder bores and radially reciprocating working pistons of the second cylinder block differs from the number of cylinder bores and radially reciprocating working pistons of the first cylinder block, and a second circumferential cam lobe surface with which the working pistons of the second cylinder block can interact, is arranged in the front casing on its radial inner side.

20. The hydrostatic radial piston unit according to claim 19, wherein the second circumferential cam lobe surface is formed integrally with the front casing.

21. The hydrostatic radial piston unit according to claim 1, wherein a reinforcing front cover is attached to a front end of the rotary casing, which closes the rotary casing, wherein the front end and the reinforcing cover are designed such that the reinforcing cover is capable of absorbing forces acting on the rotary casing in radial direction.

22. The hydrostatic radial piston unit according to claim 21, wherein the reinforcing cover comprises a sleeve-like collar and the rotary casing comprises a complementary shoulder, or vice versa.

23. The hydrostatic radial piston unit according to claim 1, operated as a hydraulic motor driving a track drive or wheel of a working machine by means of the torque transmission device.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0047] In the following annexed Figures, exemplary embodiments of the hydrostatic radial piston unit according to the invention as wells as specific subassemblies of a hydrostatic radial piston unit according to the invention are described. The presented embodiments do not limit the scope of the invention. The Figures show:

[0048] FIG. 1 shows a first sectional view along the rotational axis of a hydrostatic radial piston unit according to the invention;

[0049] FIG. 2 shows a second sectional view along the rotational axis of a hydrostatic radial piston unit according to the invention;

[0050] FIG. 3 shows a third sectional view of a hydrostatic radial piston unit according to the invention;

[0051] FIG. 4 shows an isometric view of a rotary casing of a hydrostatic radial piston unit according to the invention;

[0052] FIG. 5 shows an isometric sectional view of a rotary casing with a mounted distributor of a hydrostatic radial piston unit according to the invention; and

[0053] FIG. 6 shows a partial sectional view of the front end of a hydrostatic radial piston unit according to the invention.

[0054] For illustration and legibility purposes only, in all presented Figures the same functional parts are indicated with same reference numbers.

DETAILED DESCRIPTION

[0055] FIG. 1 discloses a hydrostatic radial piston unit 1 according to the invention. The hydrostatic radial piston unit 1 comprises a stationary, non-rotary casing 20 comprising a through hole 26 which defines a rotational axis 10. The non-rotary casing 20 houses a stationary shaft 12 which is arranged coaxially with the rotational axis 10 and is in torque proof connection with the non-rotary casing 20. A rotary casing 40 is supported by means of a pair of roller bearings 90 such that it is rotatable around the rotational axis 10 in relation to the stationary casing 20. Thereby a rear end portion of the rotary casing 40 is sealed by means of a seal 37 against a front end portion of the stationary casing 20. The axial position of the seal 37 is defined by a sealing plane 35 which is orthogonal to the rotational axis 10. Seen from the outside, the sealing plane 35 splits the housing 3 of the radial piston unit 1 in a rotary casing part 40 on one side of the sealing plane 35 and a stationary casing part 20 on the other side of the sealing plane 35.

[0056] The pair of roller bearings 90 is arranged on an extension 25 of the stationary casing 20, wherein the extension 25 according to the embodiment shown in FIG. 1 is provided as an additional extension part. The extension 25 protrudes across the sealing plane 35 into the cavity which is formed by the rotary casing 40. In the embodiment shown with FIG. 1, the roller bearings 90 are arranged as a pair, i.e. substantially directly next to each other in the direction of the rotational axis and in O-configuration. O-configuration of the bearings is preferable, if the support spacing of the bearings shall be increased, e.g. if a component shall be guided with low tilting clearance or if high tilting forces must be supported. Otherwise, an X-configuration or a locating/non-locating bearing arrangement might be chosen.

[0057] According to the invention, the pair of bearings 90 are arranged in an axial overlapping area 30, in which the stationary, non-rotary casing part 20 and the rotary casing 40 overlap. In other words: In the overlapping area 30, the stationary casing 20 is arranged coaxially with the rotary casing 40 and vice versa. However, both, the stationary casing 20 and the rotary casing 40, are radially spaced from each other. This means, that the rotary casing 40 surrounds the stationary casing 20, as it is the case in the presented examples, or vice versa.

[0058] The rotary casing 40 comprises a torque transmission device 44, i.e. a flange at its outer circumferential surface 48. Depending on the application, a component can be attached to the flange 44, which can be driven by the hydrostatic radial piston unit 1 or which can drive the hydrostatic radial piston unit 1. The torque transmission device 44 is preferably arranged in the same axial position as the pair of bearings 90 in order to reduce the axial lever between the bearings 90 and the torque transmission device 44 and thereby eliminate tilting moments that would otherwise be generated.

[0059] The rotary casing 40 comprises an inwardly oriented cam-lobe surface 80 against which working pistons 60 can be pressed (see also FIG. 3). In the presented embodiment, the cam-lobe surface 80 is formed integrally with the rotary casing 40, e.g. by 3D-milling, casting. turning, forging or a different manufacturing method. The working pistons 60 are housed in cylinder bores 55 of a cylinder block 50. The cylinder block 50 is designed to be stationary with the stationary shaft 12 and the stationary casing 20. Therefore, urging/pressing the working pistons 60 against the cam-lobe surface 80 causes a force on the cam-lobe surface 80 that is supported by the stationary cylinder block 50. Due to the shape of the cam-lobes, this force causes a rotation of the rotary casing 40.

[0060] In order to urge the working pistons 60 against the cam-lobe surface 80, pressurized fluid is supplied to the cylinder bores 55 of the cylinder block 50. If, in the opposite case, a working piston 60 is driven radially inwards due to following the shape of the cam-lobe surface, i.e. a cam, hydraulic fluid is drained from the corresponding cylinder bore 55. Therefore, the cylinder bores 55 have to be alternately connected to an inlet of the hydrostatic radial piston unit 1 and to an outlet of the hydrostatic radial piston unit 1. This is accomplished by a rotary distributor 70.

[0061] The rotary distributor 70 having a T-shaped cross section with a disc-shaped part 71 and a hollow shaft part 74 is partially arranged in the axial overlapping area 30. In consequence, the pair of bearings 90 can be arranged axially in the same position as the hollow shaft part 74 of the rotary distributor 70 and radially outside of the hollow shaft part 74 of the rotary distributor 70 in the area showing the lower diameter. However, in some designs the pair of bearings 90 might also be arranged radially inside of the hollow shaft part 74 of the rotary distributor 70.

[0062] Preferably, the rotary casing 40 and the stationary casing 20 seal an internal cavity. For this, in order to facilitate manufacturing and mounting capability of the parts of the radial piston unit 1 according to the invention, end covers 45, 130 are provided at the rear end side 24 as well as at the front end 42 of the radial piston unit 1. Additionally to its function for closing the casing cavity, the front cover 45 is designed to reinforce the rotary casing 40 and therewith the cam-lobe-surface 80 in the radial direction. The front cover 45 comprises a substantially flat disc-shaped base from which a hollow-cylindrical collar 46 extends. Complementary to the collar 46, a step 47 is provided in the outer circumferential surface 48 of the rotary casing 40. After the front cover 45 is attached to the rotary casing 40, the collar 46 provides support to the step 47 in the radial direction. This additional support guarantees that the cam-lobe surface 80 maintains its shape, even if the working pistons 55 are pressed against the cam-lobe surface 80. The thickness of the collar 46 and of the base plate can be chosen depending on the required stability increase.

[0063] Additionally the front cover 45 can comprise a lightweight construction, e.g. by means of reinforcing ribs in the mainly stressed areas and cutouts/recesses in the lower stressed areas. A person with relevant skills in the art will appreciate that the functional principle of a collar 46 providing front cover 45 and a step providing casing 40 might be inverted, such that the front cover 45 can comprise a step 47 and the casing 40 might comprise a collar 46. However, other stability increasing designs which are capable of absorbing forces acting on the rotary casing 40 in the radial direction are also covered by the scope of the invention, e.g. providing a dowelled joint between a substantially flat front cover 45 and the rotary front casing 40.

[0064] Additionally to its function for closing the rear end side 24 of the cavity of the two part casing of the radial piston unit 1, the end cover 130 is part of a park brake mechanism 100 whose actuation mechanism is arranged in the stationary casing 20. The park brake mechanism 100 comprises at least two brake discs 112 of which one is attached in a torque proof manner to the rotary casing 40 and the other one is attached non-rotational to the stationary casing 20. The brake discs 112 are movable in the axial direction relative to the stationary casing 20 and the rotary casing 40. If the park brake mechanism 100 comprises more than two brake discs 112, the discs 112 are connected to the stationary casing 20 and the rotary casing 40 in alternating order. A disc spring 118 supported by the end cover 130 provides a pre-tensioning force on a brake piston 116. As long as the brake piston 116 is not pressurized at its releasing surface 117, the spring force is transferred via the brake piston 116 to at least one brake pin 114 arranged in an axially oriented bore 28 in the stationary casing 20.

[0065] Preferably, to provide a more balanced actuation of the brake discs, more than one brake pin 114 is provided. The brake pins 114 are each arranged in one of circumferentially distributed axial bores 28. The at least one brake pin 114 applies/transfers the pre-tensioning force of the disc spring 118 on the brake discs 112 which are pressed against each other and supported by a shoulder of the stationary casing 20 or the extension 25, e.g. Therewith relative movement between the rotary casing 40 and the stationary casing 20 can be impeded at standstill of a working vehicle, e.g.

[0066] If relative movement between the rotary casing 40 and the stationary casing 20 shall be admitted, hydraulic pressure is applied to a releasing surface 117 of the brake piston 116 located opposite to the disc spring 118. The hydraulic pressure generates a force on the releasing surface 117 which is directed towards the rear side of the stationary casing 20, i.e. in the direction of the disc spring 118. As the generated force is directed opposite to the pre-tensioning force of the disc spring 118, the brake pins 114 are released from the brake discs 112. Thus, relative movement between the brake discs 112 and therewith relative movement of the stationary casing 20 and the rotary casing 40 is possible.

[0067] Preferably, the brake pins 114 comprise a specific geometry. The end of the brake pin 114 facing in the direction of the brake piston 116 comprises a higher diameter than the end facing in the direction of the brake discs 112. Additionally, the brake pins 114 are sealed against the stationary casing 20 and the stationary shaft 12. Therefore, a pressure chamber is formed between the end surfaces of the brake pins 114 and the casing 20 of the hydrostatic radial piston unit 1. If the brake piston 116 is urged in the direction of the brake discs 112, it pushes the brake pin 114 against the brake discs 112. If, in the other case, pressure is supplied to the sealed pressure chamber and a force is generated on the end surfaces of the brake pins 114. Due to the different diameters of the end surfaces, the pressure generates a force which urges the brake pin 114 in the direction of the brake piston 116. After the brake pin 114 is in contact with the brake piston 116, it presses the brake piston 116 against the disc spring 118 and thereby releases the axial force from the brake discs 112.

[0068] However it is also covered by the concept according to the invention that the specific design of the brake pins 114 ensures that the pins 114 are always in contact with the brake piston 116 independently whether the releasing surface is pressurized or not. In this embodiment, the brake pins 114 are sealed against the stationary casing 20 on the end facing away from the brake pistons 116. The rear end of the brake pins 114 with higher diameter is accommodated in the brake piston 116 and a seal is provided between the rear end of the brake pins 114 and the brake piston 116. Then, when the brake piston 116 is moved by the force generated by hydraulic pressure in a pressure chamber, which is formed by the brake piston 116 together with the shaft 12, the front ends of the brake pins 114 and the stationary casing 20, hydraulic pressure can be present at the rear/end surfaces of the brake pins 114. Due to the higher diameter of the end surface facing towards the brake piston 116, a higher force is generated by the hydraulic pressure on the side facing away from the brake piston 116 and the brake pin 114 is held in contact with the brake piston 116.

[0069] FIG. 2 shows a sectional view of the hydrostatic radial piston unit 1 according to FIG. 1 in a different section plane. In the view according to FIG. 2, some of the plurality of hydraulic conducts of the hydrostatic radial piston unit 1 according to the invention are shown. In the center of the hydrostatic radial piston unit 1 a stationary, non-rotary shaft 12 is provided comprising first group of grooves 13 in a region towards the end side 24 of the hydrostatic radial piston unit 1 according to the invention. The stationary shaft 12 additionally comprises a second group of grooves 14 in an area towards the front end 42 of the hydrostatic radial piston unit 1. The first group of grooves 13 form first circular conducts 33 together with annular grooves 22 provided in the stationary, non-rotary casing. These first circular conducts 33 are used to distribute hydraulic fluid conducted from the inlet of the hydrostatic radial piston unit 1 and towards the outlet of the hydrostatic radial piston unit 1.

[0070] Second circular conducts 43 are formed by the second grooves 14 in combination with second internal grooves 73 in the hollow shaft part 74 of the rotary distributor 70. The first circular conducts 33 are fluidly connected with the second circular conducts 43 by means of channels (not visible in FIG. 2) arranged in the stationary shaft 12.

[0071] From the FIGS. 1 and 2, the internal structure of the rotary distributor 70 becomes apparent. The rotary distributor 70 is capable of selectively connecting the second circular conducts 43 with the appropriate cylinder bores 55, depending on whether via the timing holes high pressure shall be supplied to a specific cylinder bore 55 or whether hydraulic fluid shall be drained from the specific cylinder bore 55.

[0072] In the shown embodiment of the invention, the extension 25 is provided as additional part which is attached to the stationary casing 20. In addition to supporting the pair of bearings 90, the extension 25 provides a shoulder against which the brake discs 112 can be pressed. Both functionalities require tight manufacturing tolerances in order to guarantee a reliable bearing and braking of the hydrostatic radial piston unit 1. Realizing both of these functionalities on a relatively small additional part comprises the advantage that only the relatively small additional part has to be machined, whereas big parts of the stationary casing 20 do not require such a complicated machining in this regard as it would do, if the stationary casing 20 should provide the shoulder and/or the bearing surface.

[0073] The stationary, non-rotary shaft 12 further comprises an axial bore 15 which, in the presented example, is arranged coaxially with the rotational axis 10. A two-speed valve 120 is arranged in the axial bore 15. The two-speed valve 120 comprises two positions. In a first position, all cylinder bores 55 can be supplied with hydraulic fluid at a high pressure. In a second position only a part of the cylinder bores 55 can be supplied with hydraulic fluid at high pressure. The other cylinder bores 55 are supplied with a lower pressure, sufficient to force the rollers of the working piston 60 to follow the cam-lobe surface. Simultaneously the cylinder bores 55 supplied with the lower pressure can be hydraulically short-circuited. Therefore, in the first position, all cylinder bores 55 constitute the working volume of the hydrostatic radial piston unit 1. In the second position, the short-circuited cylinder bores 55 do not contribute to the working volume of the hydrostatic radial piston unit 1, as for every working piston 60 moving to the outside another piston moves to the inside of its associated cylinder bore 55.

[0074] In the presented embodiment, the two speed valve 120 is operated hydraulically. However, the two-speed valve 120 might also be operated mechanically or electro-mechanically. In other embodiments, as a person skilled in the relevant art is aware of, the two-speed-valve 120 could be a multiple speed valve 120 providing further positions, to vary the rotational speed and torque of the hydrostatic radial piston unit 1 in a greater range.

[0075] FIG. 3 shows a sectional view of the hydrostatic radial piston unit 1 according to the invention in a plane which is arranged orthogonal to the rotational axis 10. The stationary shaft 12 shown in the middle of the FIG. 3 is in torque proof connection with the cylinder block 50. Therefore, the cylinder block 50 is also stationary. The cylinder block 50 comprises radially arranged cylinder bores 55 which are equidistantly distributed on the circumferential surface of the cylinder block 50. Every cylinder bore 55 receives a working piston 60, such that the working piston 60 can slide in the cylinder bore 55 in the radial direction. The working pistons 60 comprise rollers 65 at the radially outward end. The rollers 65 are forced into contact with the cam-lobe surface 80 formed at the radial inside of the rotary casing 40, when pressure is supplied to the cylinder bores 55. The pressure creates a force on the working pistons 60 which is directed radially outwards. If the rotary casing is forced to rotate, the rollers 65 interact with the cam-lobe surface 80 depending on, whether the roller 65 is travelling from a lobe to a cam or vice versa. If the roller 65 travels from a lobe to cam, i.e. the shape of the cam-lobe surface is directed radially inwards, the roller 65 and the corresponding piston 60 are forced in the inward direction by the shape of the cam-lobe surface 80 and hydraulic fluid is drained from the associated cylinder bore 55. In the opposite case, i.e. if the roller travels from a cam to a lobe, which means that the shape of the cam-lobe surface 80 in this zone is directed radially outwards, the roller and the corresponding piston 60 are urged outwardly to follow the cam-lobe surface by the pressure inside the cylinder bore 55.

[0076] FIG. 4 shows an isometric view of a rotary casing 40 which is used in one embodiment of a hydrostatic radial piston unit 1 according to the invention. Apart from the already above mentioned features, FIG. 4 shows axially oriented holes 75 which are arranged radially inside of the cam-lobe surface 80 at a surface which is perpendicular to the rotational axis 10. The axially oriented holes 75 receive distributor springs 72 that are capable of providing a pre-tensioning force onto an adjacently arranged rotary distributor 70. The disc shaped part 71 of the rotary distributor 70 and rotary casing 40 in combination with the axially oriented holes 75 and the accommodated distributor springs 72 can be coupled in a rotatable way by means of a synchronizing pin 78 arranged in one of the axially extending holes 75 of the rotary casing 40. In consequence, the rotary distributor 70 and the distributor springs 72 rotate with the same rotational velocity.

[0077] A person skilled in the relevant art detect from FIG. 4 in view of FIG. 1 or 2 that the axially oriented holes 75 can be moved to the distributor 70 also, to abut against the bottom surface of the associated lobe. Placing the distributor springs 72 in holes 75 in the distributor 70 fulfills the same function: to press the distributor 70 against the front face of the cylinder block 50.

[0078] In FIG. 4 a synchronizing pin 78 is shown also, arranged on a greater diameter as usual in the art. This lowers the shearing moment acting on the synchronizing pin 78. These shearing forces are generated in operation of the hydraulic motor by friction forces between the outer circumferential surfaces of the shaft 12 and inner circumferential surfaces of the distributor 70 sealing with the shaft 12 surfaces to from circular distribution channels (see also FIG. 1 or 2). Here, the synchronizing pin 78 is accommodated in an axial bore 75 in the front housing 40 and a corresponding hole in the distributor 70.

[0079] FIG. 5 discloses a sectional view of a rotary casing 40, in which a rotary distributor 70 is arranged. The outer surface at the disc-shaped part of the distributor 70 is formed complementary to the cam-lobe surface 80, in order to support the functionality of a synchronizing pin 78 which is accommodated in the rotary casing 40. The synchronizing pin 78 ensures, that the rotational orientation of the distributor 70 is correct, when the distributor 70 is received in the rotary casing 40. Furthermore, the synchronizing pin 78 synchronizes the rotation of the distributor 70 with the rotation of the rotary casing 40. Additionally, it is shown, how the distributor springs 72 abut against the ground of the axially oriented holes 75 and thereby press the distributor 70 in the direction of the front end 42, i.e. towards the cylinder block 50 (not shown in FIG. 5). The rotary distributor 70 comprises a lightweight design, to reduce the rotational inertia of the assembly. For that, clearances are provided at the radially extending plate-like part 71 of the distributor 70 partially. Additionally the second internal grooves 73 which are formed at the radial inside of the distributor 70 are shown. The grooves 73 comprise an annular shape and are capable of guiding fluid to and from timing holes 77 which are arranged in the front face of the distributor 70.

[0080] FIG. 6 illustrates how the reinforcing front cover 45 is attached to the rotary casing 40 by means of screws which are equidistantly distributed along an imagined circular arc. The above explained combination of a collar in the front cover 45 and a step in the rotary casing 40 not only reinforces the cam-lobe surface 80, but also guarantees that the cover 45 is centered correctly in relation to the rotary casing 40. It will be appreciated that also other techniques to attach the cover to the rotary casing are within the knowledge of a person with relevant skills in the art.

[0081] From the above disclosure and accompanying Figures and claims, it will be appreciated that the hydrostatic radial piston unit 1 according to the invention offers many possibilities and advantages over the prior art.