DE102016214422A1 - Hydrostatic axial piston machine - Google Patents

Abstract

Disclosed is hydrostatic axial piston machine with an adjustable displacement volume and a cylinder drum in which a plurality of working pistons are axially displaceable, which are supported on a sliding surface of a pivoting cradle, which is pivotally mounted for adjusting the displacement volume on a housing-fixed sliding bearing, wherein between the sliding bearing and the Schwenkwiege at least a first hydrostatic relief pressure field can be formed.

Description

The invention relates to a hydrostatic axial piston machine according to the preamble of patent claim 1.

A generic axial piston machine is for example in the document DE 10 2012 022 999 A1 shown. It is designed in swash plate design with adjustable displacement and has a rotatably connected to a drive shaft cylinder drum in which a plurality of cylinder bores are formed approximately parallel to the axis of rotation of the drive shaft. In the cylinder bores in each case a working piston is received axially displaceable. The working pistons are supported on a sliding surface of a pivoting cradle, which is pivotally mounted for adjusting the displacement volume on a housing-fixed slide bearing.

In order to improve the sliding of the pivoting cradle on the slide bearing and to relieve the friction surfaces hydrostatic discharge pressure fields are provided, which are formed in the designated swivel balancing side pressure pockets or sliding bearing side. Some of the relief pressure pockets are via a pressure medium channel with the high pressure side, or the high pressure port of the axial piston in pressure medium connection, whereas other discharge pressure pockets are on a pivoting cradle passing through pressure medium channel with a pressure chamber of an actuating cylinder or counter-cylinder of the adjustment of the axial piston in pressure medium connection.

A disadvantage of the solution is that the pressure fluid connections of the discharge pressure pockets are permanent to their pressure medium sources, whereby a permanent leakage current through the relief pressure fields and thus a pressure medium and energy loss lowers the efficiency of the axial piston.

In contrast, the invention has for its object to provide an axial piston machine with contrast, increased or increased efficiency and increased engine stability.

This object is achieved by a hydrostatic axial piston machine having the features of patent claim 1.

Advantageous developments of the axial piston machine are described in the claims 2 to 15.

A hydrostatic axial piston machine is designed in a swash plate design and has an adjustable displacement volume. It has a, in particular rotationally fixed to a drive shaft connecting cylinder drum, in which a plurality of working pistons are received axially displaceable. The latter are in particular in cylinder bores, which are formed approximately parallel to the axis of rotation of the drive shaft, added. The working pistons are indirectly or directly supported on a sliding surface of a pivoting cradle of the axial piston machine, which is mounted for adjusting the displacement volume on a housing-fixed sliding bearing, in particular on two symmetrically arranged plain bearings, in particular bearing shells, pivotable. At least one first hydrostatic relief pressure field can be formed or formed between the sliding bearing and the pivoting cradle. According to the invention, an adjustable first flow cross section is provided in a first pressure medium flow path from a first pressure medium source of the axial piston machine to the first hydrostatic pressure relief field.

With the aid of the first adjustable flow cross-section, the axial piston machine is thus prepared to provide the hydrostatic discharge in line with requirements, for example based on operating phases or operating points. As a result, a leakage loss from the relief pressure field out can be minimized, which in principle lowers the operating costs of the axial piston and can increase the volumetric efficiency of the axial piston engine. In principle, the hydrostatic discharge leads to a more precise adjustment of the displacement volume, since less static friction must be overcome, in particular at the beginning of an adjustment process. In addition, the pivoting dynamics of the adjustment can be optimized and the control or regulation of the adjustment proves more stable. The stability of the engine, while not pivoted, can be increased by increased friction.

In a development of the axial piston machine, a second hydrostatic relief pressure field can be formed between the sliding bearing and the pivoting cradle, in particular for and during the adjustment and / or return of the displacement volume. In this case, an adjustable second flow cross-section is provided in a second pressure medium flow path from a second pressure medium source to the second hydrostatic pressure relief field. By providing two or more relief pressure fields which can thus be supplied with pressure medium independently of one another, the flexibility of the hydrostatic discharge of the pivoting cradle is increased.

In one development, the axial piston machine has an adjusting device which has a hydraulic actuating cylinder for adjusting the displacement volume. This is the first one Pressure medium source can be formed over a control pressure chamber of the actuating cylinder, in particular formed.

In a development, the first adjustable flow cross section is formed in the control piston.

In a further development of the axial piston machine, the adjusting device for resetting the displacement volume to a hydraulic return cylinder, wherein the second pressure medium source can be formed via a return pressure chamber of the return cylinder, in particular formed.

In a development, the second adjustable flow cross section is formed in the return piston.

In a further development, the first relief pressure field can be acted upon by a retraction of the actuating piston in the actuating cylinder, via a reduction of the control pressure chamber, with pressure medium. In this way, otherwise relaxed to low pressure pressure medium for use in the first hydrostatic relief pressure field can be used, whereby pressure medium energy is saved.

In a further development, the second relief pressure field is acted upon by a retraction of the return piston in the return cylinder, via a reduction of the return pressure chamber, with pressure medium.

In an alternative development, the first pressure medium source is a subset of limited in the cylinder drum on the working piston working pressure chambers. In particular, the subset of those working spaces is formed, which are in pressure medium connection with a housing-fixed high-pressure chamber or high-pressure port of the axial piston machine.

In a further development, the flow cross-section is adjustable by means of two parts or components of the axial piston machine which are moved relative to one another during the change in the displacement volume as a function of the pivot angle. Thus, no separate device is provided for adjusting the flow cross-section, but it is used in any case, used in the adjustment or return moving parts of the axial piston machine. In this way, a control and device technical effort is reduced.

In a further development, an adjustment of the flow cross section is coupled to a change, that is to say an adjustment and / or return, of the displacement volume, in particular of a pivoting angle of the pivoting cradle. In this case, the coupling may be such that with increasing displacement volume or tilt angle of the flow area also increases. Alternatively, an inverse coupling is conceivable.

In a development of the pressure fluid flow path of this associated piston (piston or actuator piston or return piston), a shoe of this piston and the pivoting cradle, starting from the respective pressure chamber (working pressure chamber or control pressure chamber or return pressure space) interspersed to the respective discharge pressure field. In this way, pressure fluid flow paths are short and need not be routed through, for example, the housing wall. Due to the shortness of the pressure medium flow paths then a low pressure loss is possible.

As already mentioned, the adjustable flow cross-section of parts of the axial piston machine can be formed. Thus, in a development, for example, the flow cross-section of the pivoting cradle and the plain bearing is limited. Upon adjustment of the displacement volume, the pivoting cradle is pivoted against the sliding bearing, whereby the corresponding flow cross section changes.

Alternatively or additionally, the adjustable flow cross-section may be limited, for example, by the pair of parts pivoting cradle / working piston or pivoting cradle / sliding block or working piston / sliding block. The parts of all said pairings experience during the position or return a relative movement to each other, which can be utilized for the adjustment of the respective flow cross-section.

In a development, the adjustable flow cross-section is formed via an adjustable, in particular separately controllable, throttling device. In this development, a possibility for adjusting the flow cross-section is thus provided, which is controllable independently of the said parts of the axial piston machine which are moved during the adjustment or return. In this way, the pressure medium loading of the relief pressure fields or even more flexible.

Of course, mixed forms are possible, for example, when the first adjustable pressure flow cross-section of one of said parts pairing and the second adjustable flow cross section are formed via the adjustable throttle device, or vice versa.

In a development, the adjustable throttle device is formed via a separately controllable valve or a controllable diaphragm.

In order to build up the relief pressure fields or the particularly fast, and in this way in particular to keep a static friction between the pivoting cradle and the sliding bearing and a resulting breakaway torque small, the valve is formed in a development as a quick-acting switching valve (electromagnetically or piezobetätigt). Its switching time is in particular smaller or significantly smaller than a switching time of a valve of the axial piston machine, via which the adjusting device, in particular the actuating cylinder and / or the return cylinder, are supplied with pressure medium or are. In this way it is ensured that the structure of the relief or the pressure fields significantly faster than the control of the pivoting cradle for adjusting or resetting the displacement volume takes place.

In a development, the respective relief pressure field is limited by at least one sliding-bearing-side relief pressure pocket, which is formed in a bearing surface of the sliding bearing. Alternatively or additionally, the respective relief pressure field is limited by at least one pivoting-balance-side relief pressure pocket which is formed in a bearing surface of the pivoting cradle facing the sliding bearing. The respective relief pressure pocket can be formed for example via a flat, trough-like recess or a flat, closed groove.

In a further development, the sliding-bearing-side relief pressure pocket is overlapped at least in sections by the swivel-weighing-side relief pressure pocket. In this way, a size of the relief pressure field formed by these relief pressure pockets changes when pivoting the pivoting cradle. Thus, a relief force of the relief pressure field can be increased and / or reduced as a function of the pivot angle.

In a further development of the axial piston machine, the pivoting cradle has a neutral position in which the displacement volume is zero. In the neutral position, the sliding-bearing-side relief pressure pocket is at least partially overlapped by the swivel-weighing-side relief pressure pocket. In this case, the overlap is preferably designed in such a way that the relief pressure field increases in size as the pivoting angle and the displacement volume increase. As the displacement volume increases, so does the relieving power.

In a further development, the bearing surface of the pivoting cradle extends substantially symmetrically to a neutral plane of the pivoting cradle. In contrast to the neutral plane mentioned, the pivoting-weight-side relief pressure pocket extends asymmetrically. This asymmetry can prepare the resulting relief pressure field for a preferred swivel angle range of the axial piston machine.

In a further development, the pivoting cradle has a plurality of relief-pressure pockets which are arranged at a distance from one another in the pivoting direction and are arranged on the pivoting-balance side. Alternatively or additionally, the sliding bearing has a multiplicity of sliding bearing-side relief pressure pockets arranged at a distance from one another in the pivoting direction. By means of these multiple relief pressure pockets, the relief pressure field resulting from them can be extended over a large angular range.

In a further development, the relief pressure pockets are each supplied with pressure medium via an adjustable flow cross-section, in particular via one adjustable throttle device, or via a common adjustable flow cross-section, in particular via a common throttle device. In the first case, the relief pressure field can be flexibly constructed as needed to the tilt angle and the load case. For example, one or more of the relief pressure pockets can be controlled or removed. The second case represents a device-technically simpler, somewhat less flexible solution.

In one development, the axial piston machine has a control device, via which at least the adjustment or the adjustment and the return of the pivoting cradle are controllable.

In a further development, the at least one throttle device, in particular as a function of the pivot angle, can also be controlled via the control device.

In a further development of the axial piston machine, the control device is designed in such a way that a necessary change in the displacement volume can be anticipated via an operating profile, in particular from a progression of one or more operating parameters of the axial piston machine. In a further development, at least one flow cross-section of the one or more throttle devices can then be controlled, in particular controlled and controlled, via the control device.

Several embodiments of a hydrostatic axial piston according to the invention are shown in the drawings. With reference to the figures of these drawings, the invention will now be explained in more detail.

Show it

1 in a longitudinal section of a hydrostatic axial piston machine according to a first embodiment,

2 a hydraulic circuit diagram of the hydrostatic axial piston machine according to 1 .

3 in a schematic representation of a pressure medium source, an adjustable flow cross-section and a relief pressure field of the axial piston according to the 1 and 2 .

4 1 is a schematic representation of a pivoting cradle of a hydrostatic axial piston machine according to a second exemplary embodiment,

5 1 is a schematic representation of a pivoting cradle of a hydrostatic axial piston machine according to a third exemplary embodiment,

6 a working piston with sliding block of a hydrostatic axial piston machine according to a fourth embodiment,

7 a working piston with sliding block of a hydrostatic axial piston machine according to a fifth embodiment,

8th a schematic representation of a sliding bearing, a pivoting cradle and a working piston with sliding block of a hydrostatic axial piston machine according to a sixth embodiment,

9 1 is a schematic representation of a pivoting cradle of a hydrostatic axial piston machine according to a seventh embodiment,

10 in a schematic representation of the pivoting cradle of the hydrostatic axial piston machine according to the 1 and 2 .

11 in a schematic representation of a pivoting cradle of a hydrostatic axial piston machine according to an eighth embodiment and

12 and 13 Schematic representation of two embodiment of swing-balance-side relief pressure pockets in a developed representation.

1 shows in a longitudinal section a hydrostatic axial piston machine 1 , This is configured in the embodiment shown as a hydraulic pump and therefore has a dedicated high pressure port HD and a dedicated low pressure port ND, both on a housing cover 2 are trained and in 1 are not shown. A drive shaft 4 is about a rotation axis 3 driven in rotation and takes a cylinder drum 6 with, in the plurality of circumferentially spaced cylinder bores 8th are provided, in which in the axial direction a respective working piston 10 is guided. The working pistons 10 are each about a shoe 11 on a sliding surface 12 a pivoting cradle 13 slidably supported. The latter does not rotate but is via a positioning cylinder 14 an adjustment in their inclination adjustable. In this way, a pivot angle α, and thus a displacement volume of the axial piston machine 1 , be adjusted between a minimum pivot angle α _min and a maximum tilt angle α _max . At the minimum pivot angle α _min is the swash plate 12 perpendicular to the axis of rotation 3 , so that when circulating the cylinder drum 6 and the working piston 10 no lifting movement is generated and thus the displacement or delivery volume Vg of the axial piston machine 1 is zero. At the maximum pivot angle α _max is the sliding surface 12 maximum against the axis of rotation 3 placed so that when circulating the cylinder drum 6 and the working piston 10 the maximum delivery volume Vg _max results.

The pivoting cradle 13 is in the direction of the maximum pivot angle α _max against the actuating force of the actuating cylinder 14 over a spring 18 a return cylinder 23 prestressed, at one in the housing cover 2 inserted socket 16 is supported. The actuating cylinder 14 is, with respect to the axis of rotation 3 , the return cylinder 23 arranged opposite. When charging a signal pressure chamber 15 of the adjusting cylinder 14 with adjustable pressure means pivots the pivoting cradle 13 back to the minimum swivel angle α _min . This movement is controlled by a stop 20 inside the socket 16 is arranged, limited to the pivot angle α _min = 0 °. The signal pressure chamber 15 is on the one hand from a socket 17 in the housing cover 2 screwed on, and on the other from one to the socket 17 put on adjusting piston 26 limited. With a bottom of the actuator piston 26 this is a sliding shoe on one in the pivoting cradle 13 at the edge spaced from the pivot axis used articulation point (with ball head) supported. From the socket 16 , the stop 20 and one in the socket 16 submerged return piston 22 is a return pressure chamber 24 limited. The return piston 22 is a sliding block and a pivot point spaced pivot point (with ball head) with the pivoting cradle 13 coupled.

The pivoting cradle 13 points parallel to the pivot axis and symmetrical to the in 1 shown sectional plane two part-cylindrical bearing segments 28 on, each in one in one Bearing embedded plain bearing 30 are received pivotally. In 1 are the rear of the cutting plane arranged bearing segment 28 and the associated plain bearing 30 shown in broken lines, as they are from the pivoting cradle 13 are covered. In the plain bearing 30 are in the pivoting direction circumferentially distributed several relief pressure pockets 232 introduced, via a pressure medium source of the axial piston machine 1 can be supplied with pressure medium. In this way, a relief pressure field between the sliding bearing 30 and the swivel cradle 13 , more precisely, their bearing segment 28 , buildable.

Before the execution of the pressurizing of this relief pressure field according to the 2 and 2a will be presented, will be presented, which basic options of pressure fluid supply of relief pressure pockets and their design are proposed.

The presentation of the following 3 to 13 is very schematic.

3 shows the principle according to which one or more relief pressure pockets 32 be supplied with pressure medium to the relief pressure field between the bearing segment 28 the pivoting cradle 13 and the sliding bearing 30 building. For this purpose, a pressure medium source 36 provided, which via a pressure medium flow path 34 with the relief pressure bag 32 in pressure medium connection. The pressure medium connection is via a in the pressure medium flow path 34 arranged, adjustable flow cross-section, in particular that of a throttle device controlled. The flow cross-section can be formed, for example, from anyhow during the pivoting of the Schenkwiege relative to each other relatively moving parts, such as the pivoting cradle and the sliding bearing. Alternatively, the flow cross-section of a separately controllable throttle device, such as a valve may be formed.

According to 4 the pressure medium supply takes place a swivel weighing side relief pressure bag 32 placed in the sliding surface of the bearing segment 28 is introduced, over the work spaces 9 the axial piston machine 1 which are subjected to high pressure. Shown is the working piston 10 , which is at the sliding surface 12 is supported in the pivoting cradle. The working piston is directly on the sliding surface 12 supported and suitably sealed at this, so that the leakage in the contact area working piston 10 / Swing cradle 13 is minimal. The relief pressure bag 32 is over the pressure medium flow path 34 who is the pivot cradle 13 interspersed, with the work space 9 connected. In this case, the pressure medium flow path passes through 34 also the working piston 10 , In the pressure medium flow path 34 is the adjustable flow cross section as a separately controllable throttle device 38 educated. The relief pressure bag 32 is related to a neutral level 40 the pivoting cradle designed asymmetrically. In this case, a larger portion of the discharge pressure pocket extends 32 against the pivoting direction to increase the displacement volume. The smaller section extends in the direction mentioned.

5 shows a further embodiment, in which the separately controllable throttle device in the working piston 10 is omitted and instead the adjustable flow cross-section at the support point of the working piston 10 on the sliding surface 12 provided. Due to the relative movement of the pivoting cradle 13 relative to the working piston supported thereon 10 meanwhile results in an adjustment of the flow cross-section, which is defined by the working piston side and the pivoting-balanced-side orifice of the pressure medium flow path. In order to cover the swivel angle range of the swivel cradle is the mouth of the pressure medium flow path 34 in the sliding surface 12 designed somewhat larger, so that the displacement occurring during pivoting of the mouth of the working piston 10 against the mouth in the sliding surface 12 can be covered.

6 shows a further embodiment in which the adjustable flow cross-section 38 of geometries of the shoe 11 and the working piston 10 is trained. The pressure medium flow path 34 penetrates the working piston 10 and the shoe 11 , A first section 34a opens at the front side in a ball head of the working piston 10 a second section 34b passes through the shoe 11 from its side in contact with the sliding surface to a spherical recess in which the ball head is received.

7 shows in principle the control principle, as it already in 4 was discussed, in which the adjustable flow area as an adjustable throttle device 38 in the working piston 10 is arranged. Shown is now also the shoe 11 ,

8th shows an embodiment in which the inflow of pressure medium via a working piston 10 with sliding shoe 11 in the swivel cradle 13 he follows. The adjustable flow cross section 38 is located here between the shoe 11 and the swivel cradle 13 ,

9 shows an embodiment in which in addition to the swing-balance-side relief pressure pocket 32 a slide bearing discharge pocket 232 is provided. In the neutral position both have relief pressure pockets 32 . 232 an overlap on. If the pivoting cradle is then pivoted in the direction of increasing the displacement volume, that is to say in the direction α ⁺ , the pressure relief pocket of both discharge pockets increases 32 . 232 formed relief pressure field. Accordingly, the pivoting cradle is more hydrostatically relieved with increasing pivot angle α.

10 shows a further embodiment, with a plurality in the pivoting direction α ⁺ spaced apart, slide bearing side relief pressure pockets 232 , via the pressure medium flow path 34 with the pressure medium source 36 are fluidically connected. There is every relief pressure bag 232 via a parallel branch of the pressure medium flow path 34 connected. The relief pressure pockets thus supplied in parallel with pressure medium 232 are via a common throttle device 38 , which is designed as a separate controllable valve, can be supplied with pressure medium.

Alternatively, the pressure medium supply of the relief pressure pockets 232 according to 11 be designed. Here, each parallel branch of the pressure fluid flow path 34 its own throttle device 38 on, which is separately controllable. It would also be conceivable that there is less throttling device 38 as relief pressure bags 232 in that a throttle device is thus associated with a plurality of relief pressure pockets. In this way can schwenkwinkelabhängig the individual discharge pressure pocket 232 supplied with pressure medium or from the pressure medium supply of the pressure medium source 36 be shut off. Alternatively or additionally, each one of the relief pressure pockets 232 with a different throttle cross section of the respective throttle device 38 be supplied with pressure medium. In this way, the resulting relief pressure field at the swivel angle α and the local in the plain bearing 30 occurring forces very well adaptable.

The 12 and 13 show anti-sway relief pockets 32 in a schematic representation. Shown are each the relief pressure bag 32 and an associated mouth of the pressure fluid flow path supplying it 34 , The relief pressure bags 32 are symmetrical to the neutral plane 40 arranged. According to 12 are at every storage segment 28 the pivoting cradle 13 on both sides of the neutral plane 40 two relief pressure pockets 32 arranged. Mouths of the pressure medium flow path 34 in the respective relief pressure bag 32 are diagonally to each other, each in a corner of the generally rectangular trained relief pressure pockets 32 arranged. The relief pressure bags 32 according to 12 be over the signal pressure chamber 15 and over the return pressure chamber 24 the hydraulic pump according to 1 supplied with pressure medium. At the same time, the relief pressure pockets indicated with A become 32 over the return pressure chamber 24 acted upon with pressure medium and the B indicated relief pressure pockets 32 over the signal pressure chamber 15 ,

Notwithstanding the embodiment according to 12 shows 13 Relief pressure pockets 32 that are about the neutral plane 40 extend symmetrically to this addition. Again, the relief pressure pockets indicated with A become 32 from the return pressure chamber 24 and those indicated by B from the signal pressure chamber 15 supplied with pressure medium. Compare with the relief pressure pockets according to 12 are the according to 13 narrower, but have the same footprint.

2 shows a hydraulic circuit diagram of the axial piston machine 1 to clarify the pressure medium supply of the discharge pressure pockets 232 according to 10 for easier readability of the 2 this one in smaller than 2a is provided. The axial piston machine 1 has a high pressure line 42 and a low pressure line 44 , It is in the pump operation pressure medium from the low pressure line 44 towards the high pressure line 42 promoted. Shown in 2 are the actuating cylinder 14 at the pivoting cradle 13 attacks, as well as on the pivoting cradle 13 attacking return cylinders 23 , The axial piston machine 1 has an electromagnetically actuated 3/3-way proportional valve 46 on, about its first end position 46a when energizing the associated electromagnet a the high pressure line 42 with the signal pressure chamber 15 is brought in pressure medium connection. About an end position 46b when energizing the solenoid b of the valve 46 is taken, the Stelldruckraum 15 connected to the tank T. In the first end position 46a becomes the actuating piston 26 extended and thus the pivot angle α reduced, whereas in the second end position 46b the actuator piston 26 einfährt and the pivot angle α is increased.

The return pressure chamber 24 of the return cylinder 23 is via a 2/2-way switching valve 52 with the high pressure line 42 Can be brought in pressure medium connection. The latter is biased by a spring in a closed position and can be adjusted in electromagnetic actuation in a flow position, so that said pressure fluid connection is opened.

About a designed as a 2/2 way switching valve adjustable throttle device 38 , which is electromagnetically actuated, is according to 2 and 2a the signal pressure chamber 15 with the relief pressure bags 232 , which are arranged on the sliding side, can be brought into pressure medium connection. In 2 is an optional adjustable throttle device ( 38 . dashed lines) over which the return pressure space 24 with optional swing-weigh-side relief pressure pockets ( 32 , dashed) can be brought into pressure medium connection.

The axial piston machine 1 also has a control device ECU for controlling its displacement volume and the relief pressure field. To explain the pressure medium supply of the discharge pressure pockets 232 Let's first assume that the axial piston machine 1 is operated in a stationary state with a stationary pivot angle α. Accordingly, there is currently no adjustment of the swivel angle. At this time is the 2/2 way switching valve 52 Electromagnetically actuated, so that the return pressure chamber 24 with high pressure from the high pressure line 42 is supplied. The 3/3-way proportional valve 46 is via the control device ECU and the energization of the electromagnet a in the direction of the end position 46a adjusted so that the high pressure line 42 in throttled pressure medium connection with the signal pressure chamber 15 is. The at the swivel cradle 13 attacking forces of the spring 18 at the return piston 22 attacking high pressure and the adjusting piston 26 attacking pressure in the signal pressure chamber 15 holds the swivel cradle 13 in equilibrium, that is to say at a constant swivel angle α. Because the swivel cradle 13 currently not adjusted, is the adjustable throttle device 38 not electromagnetically actuated, so that the spring is the throttle device 38 pushes in its locked position. Accordingly, the relief pressure bag 232 not pressurized and the discharge pressure field does not exist, whereby a leak is prevented.

It should now be a reduction of the swivel angle α, which is synonymous with the fact that the control pressure chamber 15 Is to supply pressure medium. Before this takes place, via the control device ECU, the electromagnet of the throttle device 38 energized, so that its flow position the signal pressure chamber 15 with the relief pressure bag 232 combines. Accordingly, the relief pressure field between the pivoting cradle builds 13 and the sliding bearing 30 on. Downstream of time, the control of the magnet a of the 3/3-way proportional valve, so that the valve body is stronger in the direction of the first end position 46a is shifted and the flow area is increased. In order to provide said time gap between the structure of the relief pressure field and the adjustment, the throttle device 38 For example, be designed as a quick-acting valve with significantly lower switching time than the 3/3-way proportional directional control valve. With the pressure medium supply in the signal pressure chamber 15 shifts the actuator piston 26 against the hydrostatic and the spring force of the return cylinder 23 until a new balance of power on the pivoting cradle 13 has set and so the adjustment is completed. At this time, the energization of the electromagnet of the throttle device is again 38 shut off, leaving the discharge pressure pocket 232 is separated from its pressure medium supply and the relief pressure field collapses, so that further leakage is prevented over it.

When increasing the pivot angle α, the control of the pressure medium supply takes place as follows: First, before the adjustment, the electromagnet of the throttle device 38 energized, so that the pressure medium connection of the control pressure chamber 15 with the relief pressure bag 232 is manufactured and the relief pressure field can be built. Then done by switching off the energization of both electromagnets a and b of the 3/3-way proportional valve 46 via the control unit ECU, the adjustment of this valve 46 in a spring-centered center locking position 46c in which the signal pressure chamber 15 from the high pressure line 42 is separated and simultaneously via a bypass line 48 and a shutter disposed therein 50 is brought in throttled fluid connection with the tank T. Accordingly, when the actuating piston retracts 26 Pressure medium from the signal pressure chamber 15 are discharged to the tank T and at the same time a sufficiently high pressure in the control pressure chamber 15 to preserve the relief pressure field. The pivoting cradle 13 learns as long as an adjustment in the direction of the larger pivot angle α, until again equilibrium of forces on the pivoting cradle 13 prevails. Then the shutdown of the energization of the electromagnet of the throttle device takes place 38 , whereby the pressure medium connection of the control pressure space 15 with the relief pressure bag 232 is interrupted and the relief pressure field collapses.

Disclosed is a hydrostatic axial piston machine in swash plate construction, for which a hydrostatic relief pressure field can be formed between a pivoting cradle and a slide bearing. In this case, an adjustable flow cross-section is provided for demand-pressure medium supply of the relief pressure field. This is variable in particular in dependence on an adjustment or return of the displacement volume in its cross section.

LIST OF REFERENCE NUMBERS

1

 hydrostatic axial piston machine

2

 housing cover

3

 axis of rotation

4

 drive shaft

6

 cylinder drum

8th

 bore

9

 Working pressure chamber

10

 working piston

11

 shoe

12

 sliding surface

13

 pivoting cradle

14

 actuating cylinder

15

 Adjusting pressure chamber

16, 17

 Rifle

18

 feather

20

 attack

22

 Return piston

23

 Reset cylinder

24

 Restoring pressure chamber

26

 actuating piston

28

 bearing segment

30

 bearings

32; 232

 Relief pressure pocket

34

 Pressure fluid flow path

36

 Pressure medium source

38

 throttling device

39

 storage area

40

 neutral plane

42

 High-pressure line

44

 Low-pressure line

46

 3/3-way proportional directional valve

46a, 46b

 end position

46c

 blocking position

48

 bypass line

50

 cover

ECU

 control device

α

 swivel angle

α _min

 minimal swing angle

α _max

 maximum swing angle

Vg

 displacement

Vgmax

 maximum delivery volume

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 102012022999 A1 [0002]

Claims (15)

Hydrostatic axial piston machine with an adjustable displacement volume and a cylinder drum ( 6 ), in which a multiplicity of working pistons ( 10 ) are axially displaceably received on a sliding surface ( 12 ) a pivoting cradle ( 13 ) are supported, which for adjusting the displacement volume (Vg) on a housing-fixed plain bearing ( 30 ) is pivotally mounted, wherein between the sliding bearing ( 30 ) and the pivoting cradle ( 13 ) at least a first hydrostatic relief pressure field ( 32 . 232 ) can be formed, characterized in that in a first pressure medium flow path ( 34 ) from a first pressure medium source ( 36 . 15 ) to the first hydrostatic relief pressure field ( 32 . 232 ) an adjustable first flow cross-section ( 38 ) is provided. Axial piston machine according to claim 1, wherein between the sliding bearing and the pivoting cradle, a second hydrostatic relief pressure field can be formed and provided in a second pressure fluid flow path from a second pressure medium source to the second hydrostatic relief pressure field, an adjustable second flow cross-section. Axial piston machine according to claim 1 or 2 with an adjusting device ( 14 . 23 ), which for adjusting the displacement volume (Vg) a hydraulic actuating cylinder ( 14 ), wherein the first pressure medium source ( 36 ) via a signal pressure chamber ( 15 ) of the adjusting cylinder ( 14 ) can be formed. Axial piston machine according to claim 2 and 3, wherein the adjusting device ( 14 . 23 ) for resetting the displacement volume (Vg) a hydraulic return cylinder ( 23 ) and the second pressure medium source can be formed via a return pressure chamber of the return cylinder. Axial piston machine according to one of the preceding claims, wherein the first pressure medium source ( 36 ) in fluid communication with a subset of in the cylinder drum ( 6 ) via the working pistons ( 10 ) limited working pressure spaces ( 9 ). Axial piston machine according to one of the preceding claims, wherein an adjustment of the first and / or second flow cross section ( 38 ) to a change in the displacement volume (Vg), in particular a pivot angle (α) of the pivoting cradle ( 13 ) is coupled. Axial piston machine according to one of the preceding claims, wherein the pressure medium flow path ( 34 ) the pivoting cradle ( 13 ), starting from the pressure chamber ( 9 ; 15 ) to the relief pressure field ( 32 ; 232 ) is interspersed. Axial piston machine according to one of the preceding claims, wherein the adjustable first flow cross-section ( 38 ) from the pivoting cradle ( 13 ), in particular the sliding surface ( 12 ), and the working piston ( 10 ), or wherein the adjustable first flow cross-section ( 38 ) from the pivoting cradle ( 13 ), in particular its sliding surface ( 39 ), and a sliding shoe ( 11 ) of the working piston ( 10 ), or wherein the adjustable first flow cross-section ( 38 ) from the working piston ( 10 ) and a sliding shoe ( 11 ) of the working piston ( 10 ) is limited. Axial piston machine according to one of the preceding claims, wherein the adjustable first flow cross-section via a first throttle device ( 38 ), and / or wherein the adjustable second flow cross-section is formed via a second throttle device. Axial piston machine according to claim 9, wherein the throttle device via a controllable valve ( 38 ) or a controllable aperture is formed. Axial piston machine according to one of the preceding claims, wherein the relief pressure field of at least one slide bearing side relief pressure pocket ( 232 ) limited in a bearing surface of the plain bearing ( 30 ), and / or wherein the relief pressure field of at least one pivot-roll-side relief pressure pocket ( 32 ), which is in a plain bearing ( 30 ) facing storage area ( 39 ) of the pivoting cradle ( 13 ) is trained. Axial piston machine according to claim 11 with a neutral position of the pivoting cradle ( 13 ), in which the displacement volume (Vg) is zero, and in which the sliding-bearing-side relief pressure pocket ( 232 ) from the swing-roll-side relief pressure bag ( 32 ) is overlapped at least in sections. Axial piston machine according to claim 11 or 12 with a neutral plane ( 40 ) of the pivoting cradle ( 13 ), in which the pivot axis lies, and to which the bearing surface ( 39 ) of the pivoting cradle ( 13 ) substantially symmetrical and the swing-weigh-side relief pressure pocket ( 32 ) extend asymmetrically. Axial piston machine according to one of the preceding claims with a plurality in the pivoting direction spaced from each other, sliding bearing side relief pressure pockets ( 232 ), and / or with a plurality in the pivoting direction spaced from each other arranged swing-balance-side relief pressure pockets. Axial piston machine according to one of the preceding claims, wherein a plurality of Relief pressure bags ( 232 ) via an adjustable flow cross section ( 38 ) or via a common adjustable flow cross-section ( 38 ) can be supplied with pressure medium.

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