DE4439899A1 - Variable output volume displacement hydraulic machine - Google Patents

Abstract

The hydraulic pump is designed to give a variable output. During a cycle of the opposed stroke pump units, the respective suction stroke chamber portions are filled by fluid portions displaced in the pressure stroke without the occurrence of a loss of working pressure to the suction pressure. The stroke volume of one pump unit is pressure-dependently divided into two portions. There is an active displacement portion, which is directed to the user equipment, and a passive displacement portion which is circulated inside the displacement machine as an idling flow.

Description

The invention relates to a method for automatically changing the Delivery volume of a displacement machine depending on the torque tan load of a connected consumer in a hydro static system by hydromechanical change of the conveyor hubes and an associated displacement machine, especially one Hydro piston pump.

Different operating states that change in short succession, often lead to the drive and the regulation of labor seem to be problems. So z. B. Press characteri siert that their running gear in a rapid advance, performs a working stroke and a rapid return. Kick extreme operating conditions, a high speed / very small resistance and low speed / high media pressure, on.

It is a procedure for automatically changing the funding volume menstroms known (DE 28 20 548 A1). A real volume control is not possible. Rather, it is a power limitation  and a reduction in performance after exceeding a pre given maximum pressure. Below the maximum pressure the known pump works like a conventional positive displacement machine and after exceeding the maximum pressure is only a zero convey possible.

When converting mechanical energy into hydraulic Energy or vice versa encounter considerable difficulties the hydraulic machines, especially when higher pressures and a re success should be sought.

To generate the in hydrostatic systems, for. B. hydraulic Pressing, the hydraulic energy required will be under various displacement pumps used. A hydro piston engine machine, such as B. a positive displacement pump is as a thrust piston machine for an automatic change of the delivery volume depending the current load of a connected consumer leads. The consumers in such systems are usually Hy draulic motors, of which, in principle, the same types Use, as with the hydraulic pumps.

In this context is the group of the displacement machines the thrust piston machines of interest, of which e.g. B. the Bauar plunger machines, piston machines, parallel piston machines axial piston machines and radial piston machines come. The volume flow rate on these machines can vary Change in speed, filling time (partial filling when speed increases hung) or the piston stroke.

The present invention has for its object a method  ren and to find a device through which an automatic Regulation of the volume flow depending on the current load power of the consumer.

The task is performed on the basis of the procedure solved genus according to the invention characterized in that that in a multi-cylinder displacement machine between couple have pump units operating in push-pull mode during a Game of the pump units each suction stroke space by im Displacement of displaced liquid can be filled without that the working pressure is reduced to the suction stroke. This teaching is based on the idea of not increasing the piston stroke change, but different volumes in a cylinder and move in a work room, in the simplest case a spring force of the load on the part separating the rooms, Pressure force keeps the balance. This component is in the suction stroke pressed against the working piston by the working pressure, to a balance of forces between the pressure force and the counterforce occurred in the axial direction. During this phase of Suction strokes run synchronously in working piston and relative body common direction. Once the system is in balance, the component in question comes to a standstill, so that it is now closed a relative movement between the working piston and the mentioned Part comes to the bottom dead center position of the piston.

The working piston sucks this during this phase of the suction stroke volume to be funded in the subsequent working stroke. In work stroke the working piston and the mentioned part move first  together and without relative movement to each other in the direction of top dead center until the part in question in top dead center point position comes to a standstill. Now the repression begins Delivery volume from the cylinder area to the surrounding work area and from here to a work management.

The stroke volume displaced during the offset phase in the working stroke is in the simplest case described here in the work room only shifted as a pendulum volume, since the associated second pump unit works in exactly the opposite direction. With that, he fills that part of the displaced pendulum volume of the first pump unit the space from an analog part of the second pumping unit is released during its suction stroke.

During the working cycle of a pump unit, therefore, only one comes in pressure-dependent variable delivery volume in the work management, the can fluctuate between zero and the piston stroke volume, depending on the position of the mentioned part to the piston. With that, too at high pressures the delivery volume flow quickly and without additional mechanical adjustment device the requirements of be adapted to the respective consumer.

According to further features, it is provided that the stroke volume is one Pump unit each pressure-dependent in an active delivery volume Share that is led to the consumer and a passive one Volume share is divided, with the passive volume share as Reactive current is circulated within the displacement machine. In order to can the pendulum volume moved during a work cycle in a currently dormant portion, the size of which only ar  pressure-side change is varied and in a dynamic Share be divided, which in turn from two sub-volumes consists. One part of the volume commutes in the work area, while the other part of the volume circulates between the cylinder annuli liert.

It is also advantageous that a pressure-dependent variable portion the passive funding volume share in a separate room as Storage volume is temporarily stored. This makes it a variable Delivery volume possible with variable pressure.

Other procedural features are that the size of the cylinder space of the respective pump unit by a pressure force is changed, which is predetermined by a spring force Size and characteristic curve is kept in balance. Thereby can be a spring force generated by various means be set.

It is also advantageous that the process and / or device Conditional leakage oil quantities within the displacement machine continuously Lich be replaced from an oil supply.

The task is performed on the basis of the device solved at the beginning of the genus according to the invention, that in each cylinder block a pair of complementary pumps units are connected to a linear actuator that each pump unit with a by means of a coaxial to the working piston  changeable cylinder space is provided, that each pump unit has a working space that the Workrooms are connected to each other, and that the float by either directly against a spring force to pump one unit characteristic spring is displaceable or that the Floats indirectly against a hydraulic shaft arranged outside the respective work area, for several Pump units equally effective spring force of a central spring which is displaceable relative to the working piston, each pump unit has a cylinder annulus and all cylinder annuli are interconnected. This is in the area of design data an automatic change in the flow rate in Ab dependence of the load of the respective consumer without additional mechanical adjustment device possible.

In an embodiment of the invention it is provided that each pump unit with a suction channel and a suction valve Working piston and an associated ver with a pressure valve see floating body. This will suction valve and Pressure valve carried along with the support element.

It is also advantageous that the floating body in each case Cylinder block is guided.

A further development provides that in a control volume Memory the central spring is arranged in a spring chamber. There through the individual characteristic springs under the respective Float saved.  

An improvement is that the work rooms by a Working ring line and all cylinder ring spaces through a ring are connected to the channel and at least half the largest possible ring displacement volume of all cylinder annulus spaces Storage space corresponds. This means that very compact hydraulic pistons can be used machines, with a suitable number of pump units practical table in any desired size.

Another embodiment provides that leakage oil compensation direction is provided, the spring chamber and a leak oil chamber has, which with the control volume storage space of the control volume Memory is connected. By appropriate dimensioning can even with the greatest leakage oil loss, the pressure in the system is maintained the.

Further features of the invention are that by a Branch line of the spring space of the actuating volume memory and the Fe the space of the leak oil compensation device to the working ring line and through a control volume line the storage space in the control volume memory are connected to the ring channel. Thus the Ring channel together with the control volume line a hydraulic Wave between the cylinder rooms and the storage volume memory room. Since all lines can also be designed as line bores are compact. Unit with all functions be created.

In a further embodiment it is proposed that the counterforce the central spring in the control volume memory at least partially  means of a gas spring can be generated in a gas spring storage space. This will bring the pump characteristic curve closer to the ideal one Traction hyperbola reached.

The invention is further developed in that a Pump unit is designed as a leak oil pump, the cylinder space via a leak oil delivery line to the leak oil chamber of the leak oil same device and this with the storage volume storage space connected is. This causes the system-related leakage oil flow continuously replaced and, by standardizing construction share achievable manufacturing advantages.

The development of the invention leads to the leak oil same device and the control volume memory to a Saugvo Lumens are brought together in such a way that a common Leak oil / storage volume storage space is present and the leak oil delivery line directly to the ring channel and further via a Control volume line to the common leak oil / control volume storage is connected.

It is also advantageous that the pump unit is lightweight built-in and removable cartridge is designed that a barrel bushing, the float, the working piston, the characteristic spring and possibly a return spring and a slide shoe. The This allows the system to operate on completely different hydraulic piston dimensions machine types are transferred.

It is also advantageous with regard to the area of application that  one or more pump units as unregulated piston pumps, so-called Base load pumps are used.

The drive transmission to the pump units requires one Traction to a drive hub, which is normally caused by Return springs is effected. This is advantageous Non-positive now achieved that the working piston of the Pump units, the working piston as a base load pump and the Working piston of the leakage oil pump as a step piston for a hydrau pressure of the working pistons against the drive lifting surface are executed.

Furthermore, it is economical in terms of manufacture, replacement maintenance and that the pump units, the leak oil pump, the base load pumps, the leak oil compensation device, the Saugvo lumen controller, the actuating volume memory and / or the gas spring valve cher each in cartridge form and all units can be installed within a pump housing. This can be a corresponding modular system for use in various types Hydro piston machines are created.

Embodiments of the invention are shown in the drawing represents and are described in more detail below.

Show it

Fig. 1 is an axial cross-section through an axial piston engine in boxer arrangement block circuit

Fig. 2 is an axial cross-section as Fig. 1 by a Hydrokol benmaschine (row or axial piston machine) with suction volume control in the block diagram,

Fig. 3 is an axial cross section of a hydraulic piston machine configured as a radial piston pump,

Fig. 4 shows an axial section through a pump unit in cartridge construction and

Fig. 5 is an axial section of a hydraulic piston machine configured as a axial piston pump.

. With reference to FIG method is tert below erläu 1 and 2: The hydraulic piston engine has a cylinder block 1, in which at least two pump units 4 a and 4 b in a working space 7 a, 7 are disposed b and connected to a lifting drive. 5

Each of the complementary pump units 4 a and 4 b has a working piston 2 a, 2 b, which is guided in the cylinder block 1 , and a floating body 6 a and 6 b coaxial with this.

The floats 6 a and 6 b are to the working pistons 2 a and 2 b and the pump units 4 a and 4 b are each relatively axially movable to the cylinder block 1 .

The working piston 2 a, 2 b each perform a suction stroke and subsequently a pressure stroke, liquid being sucked from a suction chamber 38 a, 38 b via a suction channel 11 into a respective cylinder chamber 3 a, 3 b and as a delivery volume from this into the working space 7 a, 7 b is pushed. Both the cylindrical chambers 3 a, 3 b and the Ar beitsräume 7 a, 7 b are pressure-dependent variable in size by the axially movable float 6 a, 6 b immediacy bar in each case against a spring force of its to a pumping unit 4 a, 4 b belonging characteristic spring 8 a, 8 b or indirectly via a hydraulic shaft against an outside of the respective working space 7 a, 7 b arranged for all pump units 4 a, 4 b equally effective spring force of a central spring 9 .

In such a multi-cylinder displacement machine, the pump units 4 a and 4 b work in push-pull. During a game of the pump units 4 a and 4 b, suction stroke space portions are filled up by liquid portions displaced in the pressure stroke without the working pressure being reduced to the suction stroke.

When a floating body 6 a, 6 b is supported directly on the characteristic spring 8 a, 8 b, the floating body 6 a, 6 b slides back and forth on the working piston 2 a, 2 b in the axial direction in the working space 7 a, 7 b.

Each pump unit 4 a, 4 b has the working piston 2 a, 2 b provided with a suction channel 11 and a suction valve 12 and the associated floating body 6 a, 6 b provided with a pressure valve 13 .

As far as the pressure-dependent position of the float 6 a, 6 b allows this, the working piston 2 a, 2 b sucks the medium during the suction stroke via the suction channel 11 with the suction valve 12 open and presses it during the working stroke with the pressure valve 13 open into the work space 7 , into a working ring line 16 and from there via a check valve 39 into a working line 40 leading to the consumer. On the other hand, the float 6 a, 6 b is supported indirectly via a hydraulic shaft against the spring force of the central spring 9 , then the float 6 a, 6 b in the cylinder block 1 are guided. Arisen, changeable cylinder annular spaces 10 a, 10 b are all connected to one another by an annular channel 17 . The resulting, also changeable work spaces 7 a, 7 b are connected by the working ring line 16 . The pressure stroke is concluded according to FIG. 1 for the pump unit 4 b via the stroke drive 5 . In contrast, the suction stroke, which is brought about by the force of a return spring 32 , has ended for the complementary pump unit 4 a. The working piston 2 a generates a negative pressure in the cylinder chamber 3 a, whereby the pressure medium is sucked through the suction channel 11 into the cylinder chamber 3 a. Now the pressure stroke begins via the stroke drive 5 (left side) and conveys the pressure medium via the pressure valve 13 in the float by 6 a into the working space 7 and from there through the working ring line 16 into the working line 40 . The stroke volume of the pump unit 4 a, 4 b is each pressure-dependent into an active delivery volume portion, which is fed into the working line 40 , and a passive volume portion, the passive volume portion being circulated as reactive current within the displacement machine. A pressure-dependent variable portion of the passive volume portion is temporarily stored in a control volume memory 14 and there in a control volume storage space 18 .

The size of the cylinder chamber 3 a, 3 b of the respective pump unit 4 a, 4 b is changed by a compressive force, which is held by a spring force, the characteristic spring 8 a, 8 b or alternatively by the central spring 9, the balance ver The run and size of the springs are specified and specified.

After a further process step, process and / or device-related leakage oil quantities within the displacement machine are continuously replaced via a leakage oil delivery line 28 provided with a check valve 41 and a leakage oil compensation device 19 .

In the control volume memory 14, the central spring 9 is arranged in a (first) spring chamber 15 °. At least half the largest possible annulus stroke volume of all cylinder annuli 10 a, 10 b corresponds to a control volume storage space 18 . In the actuating volume storage space 18 , an actuating piston 42 slides, which is supported via a central spring 9 and a separating piston 43 on a gas spring 24 . Thus, the counterforce of the central spring 9 is at least partially testable by means of the gas spring 24 in the gas spring storage space 25 .

Through the control volume line 23 , the control volume storage space 18 is connected to the ring channel 17 and thus to the respective cylinder derringraum 10 a, 10 b. A branching branch line 22 connects the working ring line 16 with the (first) spring chamber 15 of the actuating volume memory 14 and a (second) spring chamber 20 of a leakage compensation device 19th

There is also the leakage oil compensation device 19 , in which there is a stepped piston 44 , with its smaller piston area a leakage oil chamber 21 and with its larger piston area, the spring chamber 20 , in which an adjusting spring 45 is inserted biased, limited.

The leakage oil chamber 21 is connected to the spring chamber 20 by a bypass channel 47 provided with a check valve 46 . The connection of the oil leakage space 21 with the control volume storage space 18 of the control volume storage 14 is made by a throttle return check valve line 48 .

Each pump unit 4 a, 4 b can be designed as a leak oil pump 26 , the leak oil pump cylinder chamber 27 of which is connected via a leak oil delivery line 28 to the leak oil chamber 21 of the leak oil compensation device 19 and the latter to the actuating volume storage chamber 18 .

According to Fig. 2 of the memory control volume 14 and the Leckölaus same device shown pulled together to form a unit 19 as Saugvolumenregler 29th For this purpose, the actuating volume storage space 18 and the leakage oil space 21 are brought together in such a way that a common leakage oil / actuating volume storage space is created, the leakage oil delivery line 28 being connected directly to the annular channel 17 and further via the actuating volume line 23 to the common leakage oil / actuating volume storage space. The common leakage oil / control volume storage space and the spring space 20 are just if connected by the bypass valve 46 provided with the bypass channel 47 . The branching branch line 22 here also connects to the bypass duct 47 and to the spring chamber 15 .

The cylinder block 1 is closed by means of a housing cover or ring 49 , in which the working ring line 16 as well as the working line 40 leading to the consumer and the check valve 39 are arranged.

Referring to FIG. 3, the process is transferred to the structural design of a radial piston pump. The radial piston pump is valve-controlled. A drive shaft 50 is designed as an eccentric shaft, whereby the linear drive 5 is obtained.

Axially secured shaft bearings 53 and 54 are arranged on the drive shaft 50 by bearing covers 51 and 52 , respectively. Between the shaft bearings 53 , 54 designed as roller bearings, balancing disks 55 and 56 are arranged on both sides, and an eccentric ring 57 with an eccentric bearing 58 is provided between them. At the Ex center bearing 58 , the already mentioned drive lifting surface 37 is available.

The pump unit 4 a, 4 b is designed as a cartridge 30 that is easy to install and remove and is inserted in the cylinder block 1 . The cylinder block 1 is surrounded by a housing ring 49 and the existing joint is sealed by sealing rings 59 . In the cylinder block 1 , a working line connection 60 and a suction line connection 61 are provided.

A flange tube 62 for receiving a drive motor, not shown, is also attached to the cylinder block 1 . The suction chamber 38 is bounded by the stepped bore wall 63 and by the bearing cover 51 , 52 and connected to the suction line connection 61 .

The pump units 4 a, 4 b are each designed as cartridges 30 and arranged in a star shape in the cylinder block 1 . The cartridges 30 usually in turn each contain a pump unit 4 a, 4 b etc., but can also accommodate a base load pump 34 , a leak oil leveling device 19 , a control volume accumulator 14 , a Gasfe derspeicher 24 or a suction volume regulator 29 . The Ar beitskolben 2 a is pressed into the top dead center position by the eccentric ring 57 which generates the stroke. In this position, the Ar beitskolben 2 b reached its bottom dead center in the suction stroke.

Both pump units 4 a, 4 b are connected to one another via the ring channel 17 arranged in the cylinder block 1 , to which further pump units are also connected.

As far as the pressure-dependent position of a float 6 a, 6 b allows it, the working piston 2 a, 2 b etc. sucks the medium during the suction stroke via the suction channel 11 and presses it into the changeable working space 7 a, 7 b during the working stroke or in the working ring line 16 and from here to the Arbeitslei line connection 60th The working spaces 7 a, 7 b of the individual Pumpeinhei th 4 a, 4 b are connected to each other by the enlarged working space 7 incorporated into the housing ring 49 , which simultaneously represents the working ring line 16 .

The internal processes are explained in more detail below with reference to FIG. 4 (or the other figures), in which a pump unit 4 a or 4 b is shown as a floating cylinder pump in a cartridge construction.

The constant stroke of a working piston 2 ( 2 a, 2 b) is introduced via the drive lifting surface 37 , on which the foot of the relevant working piston 2 ( 2 a, 2 b) designed as a sliding shoe 33 is supported. The working piston 2 ( 2 a, 2 b) is designed as a hollow piston and, as shown, constructed as a two-part, stepped working piston.

In the area of its larger diameter, it is slidably mounted directly in a bushing 31 . The actual working piston 2 ( 2 a, 2 b) is pressed into the foot piston area on one side. On its free end, the floating body 6 ( 6 a, 6 b) slides in the form of a floating cylinder which is in turn slidably mounted in a smaller bore in the bushing 31 . The suction valve 12 is arranged in the working piston 2 ( 2 a, 2 b) and the associated pressure valve 13 is placed in the floating body 6 ( 6 a, 6 b). The installation location of the suction valve 12 and that of the pressure valve 13 can vary in the axial direction at least for the suction valve 12 according to structural requirements.

In the suction stroke, the working piston 2 ( 2 a, 2 b) pulls the medium from the suction chamber 38 into the cylinder chamber 3 ( 3 a, 3 b) via the suction channel 11 and the suction valve 12 . In the present case, the resetting of the working piston 2 ( 2 a, 2 b) is not effected as usual by a return spring 32 , but takes place by a hydraulic force acting on the annular surface 64 of the stepped working piston 2 ( 2 a, 2 b) in the area of the cylinder annulus 10 ( 10 a, 10 b). This compressive force constantly maintains the frictional connection between the drive stroke surface 37 and the respective working piston 2 ( 2 a, 2 b).

The size of the current suction volume depends on the rela tive position of the float 6 ( 6 a, 6 b) to the working piston 2 ( 2 a, 2 b).

This position is determined by the working pressure and the characteristics of the central spring 9 . For each pump unit 4 a or 4 b and working game, any volume between zero and the dimension-related working piston stroke volume can be conveyed. The work cycle is divided into an offset phase and a suction phase in the suction stroke as well as an offset phase and an exhaust phase in the working stroke.

During the offset phases, the pendulum volume is shifted within the respective range from one pump unit 4 a to the other pump unit 4 b. In the suction and exhaust phase, however, the delivery volume is transported from the suction chamber 38 into the working chamber 7 through the hollow working piston 2 a or 2 b and the cylinder chamber 3 a or 3 b. Is provided for the case that a hydraulic pressing of the working piston 2 a and 2 b of the Antriebshubfläche 37, is also during these phases on the side of the cylinder annular space 10 a and 10 b a pendulum volume exchange instead.

The functionality of the hydraulic piston pump is based on the circulatory ability of pendulum volume portions in the working space 7 and in the cylindrical annulus 10 a or 10 b and a variation of the actuating volume depending on the currently required working pressure.

Furthermore, there is a suction volume controller 29 which is capable of temporarily accommodating a pendulum volume that is not currently required as the control volume from the circuit into a leakage oil / control volume storage space 18 , 21 , in order to change it back into the cylinder annulus 10 a or changed operating conditions. 10 b to deliver, the changes taking place automatically and depending on the pressure. The suction volume regulator 29 can also be designed in a cartridge design.

In the cylinder annulus-side duct and line system, the corresponding pendulum volume circulates from one pump unit 4 a to the other pump unit 4 b, as long as the pump units are subjected to a quasi-steady-state working pressure from the consumer side.

In the event that a pressure change occurs in the working space 7 , part of the pendulum volume is pressed as a control volume into the leakage oil / control volume storage space when there is an increase in pressure until there is again a balance between the spring force of the central spring 9 and the pressure force on the storage space side. With a decrease in the operational working pressure, the reverse process takes place, ie a corresponding portion of the actuating volume withdrawn from the shuttle traffic and immobilized in the actuating volume storage space 18 is reintroduced into the circulation circuit as an alternating volume.

The displacement force required for this results from the now predominant spring force of the central spring 9 .

The components described so far are used to implement pressure-dependent volume flow control under the theoretical requirement of a leak-free construction. Leak-free devices cannot be implemented due to functional and production-related reasons. The solution described below continuously replaces a continuously flowing loss volume flow. For this purpose, the leakage oil pump 26 (leakage oil pump working piston 36 , leakage oil pump cylinder chamber 27 ) and the leakage oil compensation device 19 are provided.

The leakage oil pump 26 is integrated in the cylinder block 1 . The leakage oil compensation device 19 is part of the suction volume controller 29 .

The leak oil / control volume storage space of the suction volume controller 29 must not only be able to accommodate the maximum control volume, but also to store a required volume that is used during the suction stroke of the leak oil pump to compensate for the leakage oil losses occurring during this time in the system. In the leak oil / Stellvolu men storage space of the leak oil compensation device 19 of the step piston 44 (pressure compensator) as well as from the control volume memory 14 of the control piston 42 and the central spring 9 are housed.

In the event of excess delivery of the leakage oil pump, the Stufenkol ben 44 moves in the direction of the spring chamber 20 and excess leakage oil delivery volume of the leakage oil pump 26 is channeled via the bypass channel 47 and the check valve 46 into the branch line 22 and thus into the working line 16 .

During the suction phase, however, a volume loss in the system is compensated for by the pressure ratio of the stepped piston 44 and the force of the actuating spring 45 .

According to Fig. 5 has an axial piston pump includes a cylinder block 1 with the pump units 4 a and 4 b on whose working piston 2 a, 2 b are driven by a linear actuator 5, which consists of a swash benantrieb ticket. The drive shaft 50 is mounted in shaft bearings 53 , 54 and an axial bearing 65 arranged in the cylinder block 1 and in the bearing cover 51 . The shaft bushing is sealed by means of a shaft seal 66 . Likewise, the housing cover 49 and the bearing cover 51 are sealed by means of sealing rings 59 against medium out.

In the cylinder block 1 , several pump units 4 a, 4 b, etc., are distributed evenly over the circumference. The stroke drive 5 is located in a suction space 38 with the suction line connection 61 . In the cylinder block 1 is the ring channel 17 and connected with this a connection 67 for the control volume line 23 , in the event that the suction volume controller 29 is to be arranged outside the pump housing.

The working pistons 2 a, 2 b rest on the stroke drive 5 , the un different stroke position of the working pistons 2 a, 2 b being recognizable. The changeable work spaces 7 a, 7 b etc. of the pump units 4 a, 4 b etc. are in open connection with the expanded work space 7 , which also functions as a work ring line 16 . In the Ge housing cover 49 there is a working line connection 60 for the working line 40th The axial piston pump operates in the description given for FIGS. 1 to 4.

Reference list

1 cylinder block
2 working pistons
2 a working piston
2 b working piston
3 cylinder space
3 a cylinder space
3 b cylinder space
4 a pump unit
4 b pump unit
5 linear actuator
6 floats
6 a float
6 b float
7 changeable work space
7 a changeable work space
7 b changeable work space
8 a characteristic spring
8 b characteristic spring
9 central spring
10 cylinder annulus
10 a cylinder annulus
10 b cylinder annulus
11 suction channel
12 suction valve
13 pressure valve
14 actuators
15 (first) spring chamber
16 working ring line
17 ring channel
18 storage space
19 Leak oil compensation device
20 (second) spring chamber
21 oil leakage chamber
22 branch line
23 control volume line
24 gas spring
25 Gas spring storage space
26 Leakage oil pump
27 Leak oil pump cylinder room
28 Oil drain line
29 Suction volume regulator
30 cartridges
31 liner
32 return spring
33 sliding shoe
36 working piston / leakage oil pump
37 drive stroke area
38 suction chamber
38 a suction chamber
38 b suction chamber
39 check valve
40 work management
41 check valve
42 actuating pistons
43 separating pistons
44 stepped pistons
45 spring
46 check valve
47 bypass channel
48 Throttle check valve line
49 Housing cover or ring
50 drive shaft
51 bearing cap
52 bearing cap
53 shaft bearings
54 shaft bearings
55 balancing disk
56 balancing disk
57 eccentric ring
58 eccentric bearings
59 sealing ring
60 work line connection
61 Suction line connection
62 flange tube
63 bore wall
64 ring surface
65 thrust bearings
66 shaft seal
67 connection

Claims (19)

1. A method for automatically changing the delivery volume of a displacement machine as a function of the instantaneous load of a connected consumer in a hydrostatic system by hydromechanical change in the delivery stroke, characterized in that in a multi-cylinder displacement machine between paired pumping units, during a game of the pumping units, each suction stroke -Space parts are replenished by displaced liquid parts in the pressure stroke without the working pressure being reduced to the suction pressure. 2. The method according to claim 1, characterized, that the stroke volume of a pump unit in each case depending on pressure an active funding volume share that ge to the consumer leads, and a passive volume share is divided, the passive volume fraction as reactive current within the Displacement machine is circulated.   3. The method according to claim 2, characterized, that a pressure-dependent variable portion of the passive volume share in a separate room as the control volume between is saved. 4. The method according to any one of claims 1 to 3, characterized, that the size of the cylinder space of each pump unit is changed by a compressive force by a spring the balance due to predetermined size and characteristic is held. 5. The method according to any one of claims 1 to 4, characterized, that procedural and / or device-related leakage oil quantities within the displacement machine continuously from one Oil reserve to be replaced. 6. Displacement machine, in particular hydraulic piston pump, such as. B. a thrust piston pump, with an automatic change in the delivery volume depending on the current load of a connected consumer, wherein a piston is axially movable relative to the cylinder and a suction stroke can be generated in a cylinder, and subsequently a delivery volume is displaced from a cylinder chamber in the pressure stroke, thereby characterized in that in a cylinder block ( 1 ) a pair of complementary pump units ( 4 a, 4 b) are connected to a linear actuator ( 5 ), that each pump unit ( 4 a, 4 b) with a by means of a coaxial to the working piston ( 2 a, 2 b) movable float ( 6 a, 6 b) variable cylinder space ( 3 a, 3 b) is provided that each pump unit ( 4 a, 4 b) each has a working space ( 7 a, 7 b), that the working spaces ( 7 a, 7 b) are connected to each other, and that the floating body ( 6 a, 6 b) either directly against a spring force of a characteristic spring ( 8 a, 4 b) belonging to the pump unit ( 4 a, 4 b) 8 b) is displaceable or that the floating body ( 6 a, 6 b) indirectly via a hydraulic shaft against an outside of the respective working space ( 7 a, 7 b) arranged, for several pump units ( 4 a, 4 b) equally effective spring force a central spring ( 9 ) relative to the working piston ( 2 a, 2 b) is displaceable, each pump unit ( 4 a, 4 b) having a cylinder ring space ( 10 a, 10 b) and all cylinder ring spaces ( 10 a, 10 b) are interconnected. 7. displacement machine according to claim 6, characterized in that each pump unit ( 4 a, 4 b) with a suction channel ( 11 ) and a suction valve ( 12 ) provided working piston ( 2 a or 2 b) and an associated, with a pressure valve ( 13 ) provided floating body ( 6 a, 6 b). 8. displacement machine according to one of claims 6 or 7, characterized in that the floating body ( 6 a or 6 b) in each case in the cylinder block ( 1 ) is guided. 9. Displacement machine according to one of claims 6 to 8, characterized in that the central spring is disposed in a spring chamber (15) (9) in an actuating volume reservoir (14). 10. Displacement machine according to one of claims 6 to 9, characterized in that the working spaces ( 7 a, 7 b) by a working ring line ( 16 ) and all cylinder annular spaces ( 10 a, 10 b) are connected by a ring channel ( 17 ) and at least half the largest possible annulus stroke volume of all cylinder annuli ( 10 a, 10 b) corresponds to a control volume storage space ( 18 ). 11. Displacement machine according to one of claims 6 to 10, characterized in that a leakage oil compensation device ( 19 ) is provided which has a spring chamber ( 20 ) and a leakage oil chamber ( 21 ) which stores the actuating volume storage space ( 18 ) of the actuating volume ( 14 ) is connected. 12. Displacement machine according to one of claims 6 to 11, characterized in that through a spur line ( 22 ) the spring chamber ( 15 ) of the actuating volume memory ( 14 ) and the spring chamber ( 20 ) of the leakage oil compensation device ( 19 ) to the working ring line ( 16 ), and through a control volume line ( 23 ) the storage space ( 18 ) in the control volume memory ( 14 ) are connected to the ring channel ( 17 ). 13. Displacement machine according to one of claims 6 to 12, characterized in that the counterforce of the central spring ( 9 ) in the actuating volume memory ( 14 ) can be generated at least partially by means of a gas spring ( 24 ) in a gas spring storage space ( 25 ). 14. Displacement machine according to one of claims 6 to 13, characterized in that a pump unit ( 4 a, 4 b) leads out as a leak oil pump ( 26 ), the cylinder chamber ( 27 ) via a leak oil delivery line ( 28 ) with the leak oil chamber ( 21 ) The leakage oil compensation device ( 19 ) and this is connected to the control volume storage space ( 18 ). 15. Displacement machine according to one of claims 6 to 14, characterized in that the leakage oil compensation device ( 19 ) and the Stellvolu menspeicher ( 14 ) are combined to form a suction volume controller ( 29 ) such that a common leakage oil / actuating volume storage space ( 21 , 18 ) is present and the leakage oil delivery line ( 28 ) is connected directly to the ring channel ( 17 ) and further via the control volume line ( 23 ) to the common leakage oil / control volume storage space ( 21 , 18 ). 16. Displacement machine according to one of claims 6 to 15, characterized in that the pump unit ( 4 a or 4 b) is designed as an easily installable and removable cartridge ( 30 ) which has a bushing ( 31 ), the floating body ( 6 a, 6 b), the working piston ( 2 a, 2 b), the characteristic spring ( 8 ) and possibly a return spring ( 32 ) and a sliding block ( 33 ). 17. Displacement machine according to one of claims 6 to 16, characterized in that one or more pump units ( 4 a, 4 b) are used as unregulated piston pumps, so-called base load pumps. 18. Displacement machine according to one of claims 6 to 17, characterized in that the working piston ( 2 a, 2 b) of the pump units ( 4 a, 4 b), the working piston of the base load pump and the working piston ( 36 ) of the leakage oil pump ( 26 ) as Stepped piston for a hydraulic pressure of the working piston against the drive stroke surface ( 37 ) are executed. 19. Displacement machine according to one of claims 6 to 18, characterized in that the pump units ( 4 a, 4 b), the leakage oil pump ( 26 ), the base load pumps ( 34 ), the leakage oil compensation device ( 19 ), the suction volume regulator ( 29 ), the Control volume memory ( 14 ) and / or the gas spring memory ( 25 ) each in cartridge form and all units within a pump housing can be installed.