DE102008048495A1 - Hydrostatic machine i.e. axial piston machine, for use as hydraulic motor that is driven by diesel engine of work machine has fluid flow guided over bearing part that is arranged for producing pumping effect to leakage oil connection - Google Patents

Abstract

The machine (1) has a drive shaft (4) rotatably mounted in a housing (2) by a bearing part (3). Multiple circularly distributed pistons (7) are movable with a driving pulley (6). A leakage oil chamber (9) is arranged between the pistons and the housing. A fluid flow (10) is guided over another bearing part i.e. ball roller bearing (17), between the leakage oil chamber and a leakage oil connection (8). The latter bearing part has a conical form and arranged such that a pumping effect to the leakage oil connection is produced during higher rotational speed.

Description

The invention relates to a hydrostatic machine according to the preamble of claim 1. A hydrostatic machine of the type mentioned, but with a swash plate principle, is from the DT 2527189 A1 known.

From the DT 2527189 A1 is a hydrostatic machine with a swash plate and a plurality of pistons are known, which are supported on the swash plate and can be displaced by a shaft in reciprocating motion with rotating drive of the swash plate. The shaft has a solid wall part as a drive shaft and a hollow part as an axial supply line for the hydraulic fluid. The inclined disc is located at the junction of the solid and the hollow portion of the shaft and has a recess which on the one hand with the axial supply line for the liquid and on the other hand with a crescent, provided in the rear surface of the inclined disc distributor for distributing the liquid in the piston communicates. The pistons are distributed annularly, arranged concentrically to the solid-walled part of the shaft and are supported against the back of the inclined disc. On the hollow part of the shaft, a conical bearing is arranged, which is supported on the front of the inclined disc. The inflow conditions as well as the outflow conditions of the fluid from the pump are improved and it is possible to achieve an increase in the delivery rate for high-speed pumps. The conical bearing disposed in the pump, the diameter of which increases from the inlet side of the pump toward the disk or pistons, causes an additional centrifugal effect and catches the mechanical forces caused by the reaction of the pistons to the rotating, inclined disk.

at This swashplate machine does not rotate the pistons, so a slot control of the individual pistons or a control by the individual pistons assigned individual valves must be done, what Overall, very expensive.

From the EP 0 640 183 B1 a hydrostatic machine is known, in particular an axial piston machine, with a machine housing, the housing interior accommodates a rotatably mounted engine and comprises at least one leak oil connection outward leaking leak oil space, the leakage oil including lubricating oil, which flows from the bearing points of the hydrostatic machine accommodates , And with a pump rotatably mounted on the pump device, the leak oil pumped through the drain connection to the outside, with a certain level of leakage oil sets in the lower part of the leak.

The pumping device is disposed within the housing and rotationally fixed to the engine. Therefore, additional space must be available in the housing. The pumping device, which pumps the leakage oil out of the leakage oil space to the leak oil connection, is designed here in the form of a paddle wheel, wherein the individual blades on the drive disk (reference numeral 17 in the EP 0 640 183 B1 ) and are radial and / or curved. This represents a constructive and manufacturing technology considerable effort.

Of the Invention is based on the object, a hydrostatic machine of the aforementioned type so that reduces churning losses to be avoided and in particular the efficiency of the machine can be improved at high speeds without costly design changes have to make and / or with little to vanishing, additional production costs.

These Task is solved by a hydrostatic machine having the features of claim 1. The invention has the advantage that the pumping action of an already required, stored component, which provides the invention as a conical bearing component, for suction used by leak oil. This can be an additional pumping device or dispensed with additional, constructively integrated means become. As a result, a total of a hydrostatic machine is specified, the previously solved in the art complicated properties virtually automatic and with vanishing to low constructive or production costs.

This Advantage is achieved in that a fluid flow over a first bearing means between leakage oil space and leak oil connection is guided. A fluid flow may be via the first Bearing means be guided by the entire current between Leak oil space and leak oil connection or at least a significant partial flow of the fluid flow between the leakage oil space and Leakage oil connection via and / or by the bearing means flowing therethrough. When all the fluid flow over and / or is guided by the first bearing means is the existing pumping effect is used particularly efficiently. It can but also only one, in particular essential, partial flow of flow of fluid above the first storage means flow. It is essential then that the pumping action of the first, conical Storage facility is used efficiently by a predominant Part, in particular over 50%, of said fluid stream over the conical first bearing means is forcibly guided.

The first bearing means has a conical design. The conical design results in a pumping action. It may depend on, in which direction, with respect to the fluid flow (upstream or downstream), the tapered, first bearing means tapers. This will be discussed later. For the invention is essential that the first bearing means is arranged taking into account its conical design such that - in particular at high speed - a pumping action is generated to the drain connection. If, for example, the conical design of the first bearing means leads to a centrifugal pumping action, then the envelope and / or the inner raceway and / or the outer race of, for example, rolling elements of the first bearing means and / or to achieve the direction of said pumping action Rolling elements of the first bearing means itself widening in the direction of the leak oil connection.

It is a realization of the invention that an already existing Pumping action of a conical bearing means is used to the Increase efficiency of the overall machine; this can be done with achieved a single constructive, first conical bearing means become. Then no second storage means is needed and also unavailable. To get a better kinematic leadership and To achieve support of the axial and radial forces, but can also be a total of two, three or more storage resources be provided for rotatably supporting the drive shaft. insofar the invention is not limited to that in addition to the first bearing means also be provided a second bearing means got to.

Further advantageous embodiments of an inventive Hydrostatic machine are specified in the subclaims.

A structurally integrated and no or only small additional Space requiring solution with also low, constructive Effort provides that the fluid flow through a feed channel from the leakage oil space through the first bearing means and over a discharge channel flows to the drain port. By guiding the fluid flow through a Feed channel and via a discharge channel becomes an additional structural-geometric flexibility allows, at the same time a highly integrated design allowed.

Especially can the leakage oil room itself - for example, by Arrangement of other bearings or other mechanical active elements conditioned - also spatially, for example, axially and / or be arranged radially spaced from the first bearing means. Preferably, for the introduction of feed channel and / or discharge channel and geometric conditions of the hydrostatic machine exploited and / or adapted. So For example, one of the channels could be partial in the solid material and / or in the wall of a hydrostatic Machine be introduced. This will be later on discussed in more detail. Due to the fact that the fluid flow through the Bearing means is passed, is an effective use the pumping effect achieved. As in the embodiment according to claim 1 is also in the leadership of the fluid flow through the first Bearing means through a lubrication given by the fluid flow.

A efficient geometry utilization with resulting, simpler constructive and production engineering solution is achieved by the feed channel is an axial bore / channel in the housing wall has and continues through a radial bore / channel, the leads to the first storage means. In this case, the feed channel consist essentially of an axial bore or an axial component or it may only be part of the feed channel consist of an axial bore in the housing wall. The same applies mutatis mutandis to the Radial bore. For efficient guidance and geometry utilization can both in the feed channel and in the Abführkanal both axial and radial sections and Be provided components. Both feeding and discharging devices can, at least in sections, as casting channels a casting, z. B. a cast housing be.

The above mentioned in connection with claim 3 benefits apply mutatis mutandis, when the discharge channel outgoing from the first storage means Radial bore / channel and a connection bore / channel has leads to the leak oil connection.

in the The following will be closer to preferred embodiments of the storage means received. In particular, a single storage medium or it may a plurality, for example, axially adjacent bearing means provided be. With regard to the type of bearing will be in particular hereinafter on tapered roller bearings.

A combination of the inclusion of radial and axial loads and a constructive and advantageous in terms of the flow efficiency embodiment results when the first bearing means is an outer roller bearing, in particular a tapered roller bearing. In this case, the first bearing means, over which the fluid flow is guided, a, based on the drive shaft, outer roller bearing, in particular a tapered roller bearing. By in relation to the drive shaft outer arrangement of the first bearing means is - for example, even further out of the first bearing means - created the opportunity to exploit additional space for the flow management. This achieves higher design and design flexibility. Nevertheless, it is not excluded that a further inside or bearing means lying completely inside the drive disk could have the pumping effect.

In A preferred embodiment of the invention is proposed that the outer rolling bearing is an inner ring, an outer ring and between the rings in a predetermined Pressure angle a arranged frustoconical rolling elements includes. This structure of a tapered roller bearing results in that you also with existing pumping a better, kinematic Storage, that is recording of axial and radial loads reach can. The pressure angle a is between outer Career and the center line of the camp in particular so predetermined, that needed and considering of intended operating conditions meaningful pumping action is achieved.

The Pumping action or the pump power - based on the speed - can be dependent on the pressure angle a. Therefore, the pressure angle a of the first rolling bearing or the tapered roller bearing at the design of the hydrostatic machine under consideration the intended operating speeds, the operating pressure, in particular of minimum, maximum and continuous operating pressures, as well as the expected leakage current, and the type and size hydrostatic machine. Also the other bearing parameters, such as diameter (of, for example, outer and / or inner bearing ring), size of the rolling elements, axial length of the bearing etc. are according to the required parameters, as stated above, interpretable.

at specially designed first or outer rolling bearing and / or in a standard tapered roller bearing as an outer Rolling is proposed that the frustoconical Rolling elements of the first bearing means to the piston out (in the case of a pump, for example, starting from the drive side of the pump) rejuvenate. By said arrangement, the pumping action the special or standard tapered roller bearing. there the said arrangement can also only with regard to the fluid flow be partially effective.

Around in the interpretation of the support a larger Flexibility and a higher degree of or to support torque range, is proposed that a second storage means is present, which is designed as an inner roller bearing, the frustoconical Rolling is formed and mirror image to the outer rolling bearing, and in particular indirectly, is arranged. This can occur in combination Radial and axial forces, especially larger ones Radial and axial forces, efficiently supported become. While the outer and / or the first rolling bearing designed as a conical roller bearing can / is, here also called inner rolling bearing essentially cylindrical or formed with spherical bodies be. The inner bearing would be at the not mentioned here on a pumping action. The design with cylindrical or spherical rolling elements then does not result in a mirror image arrangement, as such Rolling bearings regardless of the orientation attached can be (exception could be a shoulder ball bearing). A cylindrical or ball bearing has the advantage that a like also always directed pumping action is practically not available and therefore not considered further in relation to the invention must become. The inner storage can also be a combination consist of rolling bearing and hydrostatic discharge. The hydrostatic discharge also has the advantage that no Pumping action is present.

If - how claimed in claim 8 - the inner roller bearing is also a tapered roller bearing, it is especially mirror image and / or indirectly to the outer rolling bearing arranged. Due to the indirect arrangement of the two rolling bearings is the pumping action of the invention at the same time very high to maximum effective bearing clearance of rolling bearings realized. This will turn a highly integrated design and ensures effective power supply, up there shortest space through the proposed arrangement Axial and / or radial deviation / tilting of the drive shaft efficiently is supported.

In order to a possible opposite effect of the conically shaped inner rolling bearing is minimized until it is eliminated suggested that the inner bearing to the outer Rolling bearing by means of a flow shield, in particular by means of a sealing disc, is delimited. One maybe opposite pumping action can also by other constructive Means reduced to be eliminated, for example by a practically fluidly decoupled, geometric arrangement without a flow shield and / or in that the inner rolling bearing is not considered conical Rolling is formed.

A good to sufficient pumping effect at the same time good support of radial and axial loads is achieved in that the pressure angle a, which corresponds to the inclination of Wälzkörperachsen to a shaft axis and depending on the occurring radial and axial loads between 10 ° and 30 °. In particular, the inclination includes ranges and values of 10 ° -15 ° or 15 ° -20 ° or 20 ° -25 ° or 25 ° -30 °, in particular 15 °. In the aforementioned embodiment, on the one hand, a purpose-built bearing can be used. A particular advantage lies in the fact that in the mentioned embodiment standard tapered roller bearings can be used, which has a tilt of about 15 °. In this case, the geometric arrangement and the size, in particular the diameter and the axial length of the tapered roller bearing can be adapted and / or selected in the design still.

Practically all operating conditions occurring in the application covered with a great deal of safety by that depending on the rolling element parameters and the geometry of the feed and discharge channels a relevant pumping action of up to 10 l / min at a speed range from 500-3000 rpm, in particular ranges and values of 500-1000, 1000-1500, 1500-2000, 2000-2500 or 2500-3000 rpm is achieved. This is just a usual occurring in a hydrostatic machine of the type mentioned leakage under the operating pressures and at the operating speed range reliably dissipated.

For a variety of hydraulic applications suitable The invention is characterized in that the hydrostatic machine a Schrägachsenmaschine is, with a housing, a in the housing by means of bearing means rotatably mounted drive shaft and one connected to the drive shaft, in the housing rotatably arranged cylindrical drum having cylinder bores, in which pistons are movable. This opens up a broad field of application and also the mass market for the invention, being straight in the aforementioned embodiment according to claim to a high efficiency Such a bent axis machine arrives very strongly. The efficiency is one of the essential features or advantages such a bent axis machine.

The The invention will be described with reference to the attached figures Embodiments explained in more detail.

The 1 shows a longitudinal section through a physical embodiment of a hydrostatic machine according to the invention, the 2 shows a possible variant of a fluid flow path according to the invention in longitudinal section according to 1 ,

In the figure, the reference numeral 1 an axial piston machine in Schrägachsenbauweise refers to a housing 2 in which one by means of a bearing means 3 rotatably mounted drive shaft 4 is arranged. The shoot shaft 4 ends at a drive disc 6 representing, flange portion of larger diameter, based on the drive shaft 4 , With the drive disc 6 rotatably connected are pistons 7 , The pistons 7 are shown by resulting skew on rotation with respect to the cylinder, here the cylinder bore 27 a cylinder drum 5 , reciprocable.

These are the pistons 7 in cylinder bores 27 a cylinder drum 5 guided longitudinally displaceable. The cylinder bores 27 extend axially in a known manner and are preferably evenly distributed on a circle or pitch circle.

The cylinder drum 5 is drive shaft side via a center pin 28 at the engine disk 6 rotatable and - in particular for adjusting the working stroke of the piston 7 - pivoted. It is drive shaft downstream on a cross-section approximately oval, substantially ellipsoidal control body 30 rotatably mounted.

Both the center pivot 28 as well as the pistons 7 are outside the cylinder drum 5 to ball heads 29 formed, with which the pistons 7 in spherical camps 32 the drive disc 6 are rotatably hinged and spherically deflectable articulated.

The bearing surfaces of the cylinder drum 5 and the control body 30 are spherical with a concave or convex course and self-centering. The tax body 30 is in a circular track support and pivot bearing 31 in a graduation plate 35 slidably arranged. In the control body 30 are in a known manner, two opposing, not shown control kidneys formed, which are connected to a pressure port and a suction nozzle (both nozzles also not shown) of the axial piston machine.

The housing interior surrounds the piston-cylinder drum unit and serves as a leak oil chamber 9 for receiving during operation of the axial piston machine 1 accumulating leak oil. The leak oil room 9 is with the leak oil connection 8th connected.

This in 1 illustrated storage means 3 consists of an outer and an inner rolling bearing 17 . 25 , which are each formed in the embodiment as a tapered roller bearing. Each of the tapered roller bearings 17 . 25 consists of one on the drive shaft 4 attached inner ring 18 , one on the housing 2 attached outer ring 19 and intervening, frusto-conical rolling elements 20 , The rolling elements 20 each have a truncated cone base 21 , a lateral surface 22 and a smaller surface area relative to the base area 23 , The frustoconical rolling elements 20 of the outer bearing 17 show with respect to the longitudinal axis of the drive shaft 4 by a predetermined pressure angle a (24) with the top surface 23 inclined to the longitudinal axis to the leakage oil space 9 , Overall, so the narrower deck area 23 the leak oil room 9 arranged facing, and the truncated cone base 21 essentially the leakage oil space 9 arranged away. The contact angle a and the arrangement of the frustoconical Wälzkör by 20 as well as the installation sense of the outer rolling bearing 17 are so angeord with it net, that the enveloping, outer bearing surface of the frustoconical rolling elements 20 to the leakage oil room 9 tapered towards or from the leakage oil space 9 widened away. This produces the centrifugal pumping action which allows it to be accommodated without further provisions, such as a separate pump or without structural pumping elements in the housing 2 integrate, drain the leakage oil and thus, among other things to reduce the churning losses. This has the outer rolling bearing 17 According to the invention, an essential dual function.

In the illustrated embodiment (not limiting, other embodiments are possible) is the inner bearing 25 to the outer camp 17 arranged in mirror image and indirectly. In the indirect arrangement, the effective, axial bearing distance is greater than the axial distance between the centers of the two bearings 17 . 25 , The effective bearing distance describes the distance between two points on the bearing axis in which the vertices of all conical surfaces of each rolling bearing meet. This arrangement results in tilting moments a rigid storage. Together with the invention is characterized on the one hand with the outer tapered roller bearing 17 achieved a pumping action that allows a geometrically advantageous arrangement of the Abführwege; On the other hand, at the same time a compact, ie in particular axially shorter construction is ensured at the same time stiffer and highly resilient storage. The said, indirect arrangement namely - especially at tilting moments - a more rigid and stiffer storage against a z. B. direct arrangement of two tapered roller bearings.

From the leak oil room 9 leads a feed channel 11 to the storage facility 3 and from this leads a discharge channel 12 to the leak oil connection 8th , The feed channel 11 consists of an axial bore 13 (Or possibly also a casting channel introduced in castings, this also applies to all other mentioned axial and radial and other bores) in the housing wall and is made by a radial bore 14 continue to the storage facility 3 leads. The discharge channel 12 has one from the storage facility 3 outgoing radial bore 15 and a housing bore correspondingly extending communication bore 16 leading to the leak oil connection 8th leads. A trained in a radial plane circumferential groove 33 between the two rolling bearings 17 and 25 is arranged, connects the feed channel 11 with the rolling bearing 17 deck surface side. For the formation of the channels or holes mentioned here, the housing is formed with a corresponding wall thickness. Such a wall thickness may already be present in conventional housings. For the invention, but also by small increases in the usual wall thicknesses corresponding geometry ratios for the introduction of such channels and / or holes very easily created and for the - mass production - series production can be provided.

Base surface side is the rolling bearing 17 by a circumferential groove formed in a radial plane 34 with the discharge channel 12 connected. The inner rolling bearing 25 is from the outer rolling bearing 17 through a flow shield 26 (in 1 shown in dashed lines) from the oil flow, in particular from - kinematic view - main flow of oil flow shielded.

The function of the illustrated hydrostatic machine is known to the person skilled in the art. Therefore, below, only the function of the bearing means and the path of the fluid flow 10 from the leakage oil room 9 to the leak oil connection 8th explained.

Once the hydrostatic machine is powered, and the drive shaft 4 with the pistons 7 and the cylinder drum 5 spins, among other things, churning losses occur, which increase with increasing speed and which essentially by the rotation of the pistons 7 with the cylinder drum 5 in the inside of the leakage oil room 9 located leak oil are caused. During the rotation, the oil circuit of the hydrostatic machine mainly leaks oil from the spherical bearings 32 the ball heads 29 and about that from the bearing surfaces of the cylinder drum 5 and the control body 30 formed bearings in the leak oil room 9 and flows from this via the feed channel 11 in the circumferential groove 33 to the cone top surface side of the rolling bearing 17 , At the frustoconical rolling elements 20 over and between the ring surfaces 18 . 19 the leakage oil flows through the circumferential groove 34 in the discharge channel 12 and about the leak oil connection 8th outward. Due to the truncated cone shape of the rolling elements 20 becomes the fluid flow 10 deflected by the resulting (especially centrifugal) pumping action of a conical bearing to the outside. The fluid flow 10 As a result, it experiences an acceleration in the direction of the leak oil connection 8th ,

The flow shield 26 is - referred to the direction of the fluid flow of the leakage oil flow - upstream of the inner roller bearing 25 between the inner bearing 25 and the outer rolling bearing 17 arranged. The flow shield 26 has a substantially central recess, through which the drive shaft 4 protrudes. The flow shield 26 So basically has a flat, circular floor plan. It can also decouple the bearings hydrostatically from one another and essentially also have a sealing function. In the illustrated embodiment shields the flow shield 26 but - preferably only - kinematically possibly from the inner rolling bearing 25 generated, opposing leakage oil front flow from the outer bearing 17 as a result, practically the wanted, by the outer roller bearing 17 produced discharge flow through the opposing pumping action remains unaffected.

In addition - is an approximately opposite pumping action of the inner bearing 25 reduce to eliminate - provided that the fluid flow to the inner bearing 25 completely or substantially bypassed and through the outer roller bearing 17 passed through. This may cause a flow shield 26 eliminated or - as shown - built relatively simple and the diameter also smaller than the diameter of the inner bearing 25 be provided.

There is also the possibility that the inner rolling bearing 25 a substantially cylindrical roller bearing may be substantially cylindrical rolling elements or a rolling bearing with spherical rolling elements and thus counteracting pumping virtually eliminated and thus a flow shield 26 be smaller or could be completely eliminated, since in such a case, the pumping action of the outer bearing 17 through the inner rolling bearing 25 would not be counteracted. In this case, the outer roller bearing would still, as shown, arranged to allow by such, almost half in direct bearing arrangement a larger, effective bearing distance. Furthermore, there could also be the possibility that the outer rolling bearing 17 is designed with cylindrical rolling elements or with spherical rolling elements, and that the inner rolling bearing 25 is designed as a tapered roller bearing and the fluid flow 10 in the direction of the leak oil connection 8th distracting.

This in 2 illustrated storage means 3 consists of an outer and an inner rolling bearing 17 . 25 , which are each formed in the embodiment as a tapered roller bearing. The frustoconical rolling elements 20 of the outer bearing 17 show with the top surface 23 inclined to the longitudinal axis to the leakage oil space 9 , In the illustrated embodiment, the inner bearing 25 to the outer camp 17 arranged in mirror image and indirectly. As in this embodiment, no flow shield 26 is present, the fluid flow 10 also about the inner camp 25 guided. An opposing pumping action through the inner roller bearing 25 In the embodiment shown, sealing caps are to be avoided 37 between the truncated cone bases 21 the inner rolling bearing 25 and the leakage oil space used and connecting holes 38 from the truncated cone bases 21 to the discharge channel 12 produced. The discharge channel 12 now extends to the truncated cone surface 21 the inner rolling bearing 25 , As a result, supported by the inner roller bearing 25 resulting discharge flow through the outer roller bearing 17 generated discharge flow. The two discharge flow rates add up and thus increase the pumping effect. Both bearings are sufficiently flushed by the flow path, which could replace an external bearing flush.

It It is also conceivable that one or more rolling bearings in series are arranged, wherein one or more of these rolling bearings tapered rolling elements have to the Pumping off fluid flow to the leakage oil connection. The remaining bearings could then either formed with conical rolling elements and be shielded from the fluid flow. You could as well formed with non-tapered bearings and would then on the Abpumpwirkung or Abpumprichtung do not interfere. Generally also find on the second and / or all other conical bearings or Bearing means the features of the first bearing means according to the Claims 2-12 and the description application.

Corresponding the arrangement of one or more bearings and / or the Mounting position of the hydrostatic machine can also change the location and geometry the connection holes vary, because they should be such, that the pumping effect is supported.

The contact angle a ( 24 ), which corresponds to the inclination of the Wälzkörperachsen to the shaft axis and depending on the radial and axial loads occurring between 15 and 30 °, ideally has an inclination of about 15 ° to an optimal pumping action in the high speed range of the hydrostatic machine 1 to reach. The individual holes of the feed channel 11 and the discharge channel 12 can also be realized by recesses in the housing, which are introduced during the housing casting.

The inventive design is not on the shown Schrägachsenbauweise restricted. Also in swash plate machines and essentially also in Swash plate machines, the invention can be applied. Furthermore may be a hydrostatic machine according to the invention be operated both as a pump and as a motor.

As well is the constructive solution of the cylinder drum drive not significant. Although in the embodiment the principle of bar entrainment is described, the invention may, for example also with a rotary joint principle or with a bevel gear toothing principle Find application. In any case, the inventive Benefits, in particular the advantages of increasing efficiency achieved.

1

Hydrostatic machine

2

casing

3

Bearing means; 3 ' first storage means; 3 '' second storage means

4

drive shaft

5

cylinder drum

6

drive Windscreen

7

piston

8th

Drain port

9

Oil leakage chamber

10

fluid flow

11

feed

12

discharge channel

13

axial bore

14

radial bore

15

radial bore

16

connecting bore

17

outer roller bearing

18

inner ring

19

outer ring

20

frustoconical rolling elements ( 20 ' )

21

Truncated cone base area

22

lateral surface

23

cover surface

24

contact angle a

25

inner roller bearing

26

spoiler panel

27

cylinder bores

28

center pin

29

ball heads

30

control body

31

pivot bearing

32

spherical camp

33

circumferential groove

34

circumferential groove

35

End plate

36

Lagerspülanschluss

37

sealing cap

38

connecting bores

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DT 2527189 A1 [0001, 0002]
• - EP 0640183 B1 [0004, 0005]

Claims (17)

Hydrostatic machine ( 1 ), in particular axial piston machine, with a housing ( 2 ), one in the housing ( 2 ) by means of at least one bearing means ( 3 ) rotatably mounted drive shaft ( 4 ), a plurality of annularly distributed pistons ( 7 ) with a drive disc ( 6 ), a leakage oil space ( 9 ), which between piston ( 7 ) and housing ( 2 ) is arranged and a drain connection ( 8th ), characterized in that a fluid flow ( 10 ) via a first storage means ( 3 ' ) between leakage oil space ( 9 ) and drain connection ( 8th ) and that the first storage means ( 3 ' ) has a conical design, and is arranged such that at high speed, a pumping action to the drain port ( 8th ) is generated. Hydrostatic machine ( 1 ) according to claim 1, characterized in that the fluid flow ( 10 ) via a feed channel ( 11 ) from the leakage oil space ( 9 ) by the first storage means ( 3 ' ) and via a discharge channel ( 12 ) to the leak oil connection ( 8th ) flows. Hydrostatic machine ( 1 ) according to claim 2, characterized in that the feed channel ( 11 ) an axial bore / channel ( 13 ) in the housing wall and extending through a radial bore / channel ( 14 ), which reaches the first storage facility ( 3 ' ) leads. Hydrostatic machine ( 1 ) according to claim 2 or 3, characterized in that the discharge channel ( 12 ) one of the first storage means ( 3 ' ) outgoing radial bore / channel ( 15 ) and a connection bore / channel ( 16 ), which leads to the leak oil connection ( 8th ) leads. Hydrostatic machine ( 1 ) according to one of claims 1 to 4, characterized in that the first bearing means ( 3 ' ) an outer rolling bearing ( 17 ), in particular a tapered roller bearing. Hydrostatic machine ( 1 ) according to claim 5, characterized in that the outer rolling bearing ( 17 ) an inner ring ( 18 ), an outer ring ( 19 ) and between the rings ( 18 . 19 ) at a predetermined contact angle a ( 24 ) arranged frustoconical rolling elements ( 20 ). Hydrostatic machine ( 1 ) according to claim 6, characterized in that the frustoconical rolling elements ( 20 ) of the first storage means ( 3 ) from the drive side of the pump in the direction of the pistons ( 7 ) rejuvenate. Hydrostatic machine ( 1 ) according to claim 5, characterized in that a second storage means ( 3 '' ), which is used as an inner rolling bearing ( 25 ) is formed, which with frustoconical rolling elements ( 20 ' ) is formed and a mirror image of the outer rolling bearing ( 17 ), and in particular indirectly, is arranged. Hydrostatic machine ( 1 ) according to claim 9, characterized in that the inner rolling bearing ( 25 ) to the outer rolling bearing ( 17 ) by means of a flow shield ( 26 ), in particular by means of a sealing disc, is delimited. Hydrostatic machine ( 1 ) according to claim 6, characterized in that the contact angle a ( 24 ), which corresponds to the inclination of Wälzkörperachsen to a shaft axis and depending on the occurring radial and axial loads between 10 ° and 30 °, the inclination includes in particular ranges and values of 10 ° -15 ° or 15 ° -20 ° or 20 ° -25 ° or 25-30 °, in particular 15 °. Hydrostatic machine ( 1 ) according to claim 10, characterized in that depending on the Wälzkörperparameter and the geometry of the feed and discharge channels a pumping action of up to 10 l / min at a speed range of 500-3000 U / min, in particular ranges and values of 500-1000, 1000-1500, 1500-2000, 2000-2500 or 2500-3000 rpm. Hydrostatic machine ( 1 ) according to one of the preceding claims, characterized in that the hydrostatic machine ( 1 ) is a Schrägachsenpumpe, with a housing ( 2 ), one in the housing ( 2 ) by means of storage ( 3 ) rotatably mounted drive shaft ( 4 ) and one with the drive shaft ( 4 ), in the housing ( 2 ) rotatably arranged cylindrical drum ( 5 ), the cylinder bores ( 27 ), in which piston ( 7 ) are movable. Hydrostatic machine ( 1 ) according to one of the preceding claims 1 to 12, characterized in that the fluid flow ( 10 ) via a second storage means ( 3 '' ) between leakage oil space ( 9 ) and drain connection ( 8th ), and that the second storage means ( 3 '' ) has a conical design, and is arranged such that at high speed, a pumping action to the drain port ( 8th ) is generated. Hydrostatic machine ( 1 ) according to claim 13, characterized in that current-carrying and shielding means ( 26 . 37 ) are present, the fluid flow ( 10 ) via the second storage means ( 3 '' ) such that at high speed, a pumping action to the drain connection ( 8th ) is generated. Hydrostatic machine ( 1 ) according to claim 14, characterized in that the second bearing medium ( 3 '' ) an inner rolling bearing ( 25 ), in particular a tapered roller bearing. Hydrostatic machine ( 1 ) according to claim 15, characterized in that the current-carrying and shielding means ( 26 . 37 ) in the case of indirect arrangement of the first ( 3 ' ) and second storage means ( 3 '' ) the fluid flow ( 10 ) with respect to the axial direction locally in the region of the second bearing means ( 3 '' ) practically reverse. Use of a hydrostatic machine after a of the preceding claims 1 to 16 as a diesel engine a mobile working machine driven hydraulic motor.