EP2024647A1 - Hydrostatic drive having volumetric flow compensation - Google Patents

Abstract

The invention relates to a hydrostatic drive having a first and a second hydraulic pump (11, 12) and a double-action hydraulic cylinder (2). The double-action hydraulic cylinder (2) has a first working chamber (7) and a second working chamber (8). The first working chamber (7) is delimited by a first piston face area (4) of a working piston (3) and the second working chamber (8) is delimited by a second piston face area (5) of the working piston (3). The first working chamber (7) is connected to a first connection (13) of the first hydraulic pump (11) and a first connection (14) of the second hydraulic pump (12). The second working chamber (8) is connected to a second connection (16) of the second hydraulic pump (12). A second connection (15) of the first hydraulic pump (11) is connected to a pressure-medium reservoir. The ratio of the first piston face area (4) to the second piston face area (5) differs from the ratio of the overall delivery volume of the two hydraulic pumps (11, 12) to the delivery volume of the second hydraulic pump (12). A removal valve (45) for removing pressure medium is provided for volumetric flow compensation.

Description

 Hydrostatic drive with volume flow compensation

The invention relates to a hydrostatic drive with a double-acting hydraulic cylinder and a volume flow compensation.

From DE 103 43 016 Al it is known to actuate a double-acting hydraulic cylinder by means of a first hydraulic pump and a second hydraulic pump. One of the two hydraulic pumps is with the two

Working chambers of the double-acting hydraulic cylinder connected in a closed circuit. The second hydraulic pump, however, is only connected to the piston-side working chamber in an open circuit. The two hydraulic pumps are each adjustable in their delivery volume. By setting a corresponding delivery volume ratio, the different volume flow in the piston-side working chamber and the piston rod-side working chamber is taken into account.

A disadvantage of the hydrostatic drive known from DE 103 43 016 A1 is that the ratio between the sum of the delivery volumes of the two hydraulic pumps and the delivery volume of the hydraulic pump in a closed circuit must be in the same ratio as the piston surfaces of the working piston are to each other. Consequently, if two identical hydraulic pumps are used, their respective delivery volume must be adjusted by the corresponding adjusting devices so that this condition is met. Conversely, it is necessary, when using two identical hydraulic pumps, as can be advantageously realized by using a double pump, to use a double-acting hydraulic cylinder whose piston surfaces have a corresponding ratio. In general, the two hydraulic pumps of a double pump unit are identical, so that the area ratio of the two piston surfaces would have to be 2: 1. Commercially available double-acting hydraulic cylinders However, usually have a deviating area ratio of the piston surfaces and thus different flow rates during displacement of the working piston.

It is the object to provide a hydrostatic drive, which allows for a given fixed delivery ratio of a first and a second hydraulic pump, a largely free selection of the hydraulic cylinder to be used. The object is solved by the features of claim 1. The dependent claims contain advantageous developments of the invention.

According to the invention the object is achieved in that a removal valve is provided for volume flow compensation. The hydrostatic drive comprises a first hydraulic pump and a second hydraulic pump and a double-acting hydraulic cylinder. The respective first connections of the first and the second hydraulic pump are connected together to a first working chamber of the hydraulic cylinder. By contrast, only the second connection of the second hydraulic pump is connected to a second working chamber. By contrast, the second connection of the first hydraulic pump is connected to a pressure medium reservoir. To generate a movement of the working piston, both hydraulic pumps jointly convey pressure medium into the first working pressure chamber. In the reverse conveying direction and thus the reverse direction of movement of the working piston pressure medium is conveyed into the second working chamber only by the second hydraulic pump. The ratio of the whole

Delivery volume of both hydraulic pumps to the delivery volume of the second hydraulic pump may differ from the area ratio of the first piston surface to the second piston surface. As a result, there may be a difference in the oil balance. According to the invention is a

Removal valve provided by which compensated for this difference in the oil flow balance and pressure fluid is discharged at a first conveying direction and thus a flow equalization is achieved. The removal valve preferably connects the first working chamber or the second working chamber with a pressure medium reservoir.

It is particularly advantageous to provide a purge valve as a sampling valve. The flushing valve is switched in response to the pressures in the first and the second working chamber, respectively, such that it connects the second or the first working chamber to the pressure medium reservoir. A volume flow compensation by removal of pressure medium can thus be carried out by the flush valve in each case on the side of the hydrostatic drive connected to the current suction side of the hydraulic pumps.

In this case, advantageously, a feed device can be used to connect the first or the second working chamber with the pressure medium reservoir.

In order to supplement the missing volume flow in the reverse direction of the hydrostatic drive, a feed pump is preferably provided. This promotes, in particular on the suction side of the first and the second hydraulic pump, a volume of pressure required for volume flow compensation in the hydrostatic circuit of the hydrostatic drive. Particularly preferably, the first and the second hydraulic pump are jointly adjustable in their delivery volume. In particular, they together form a hydraulic pump unit, such a hydraulic pump unit particularly preferably being a double pump whose two hydraulic pumps have an identical, adjustable delivery volume.

According to a preferred embodiment, the bleed valve is connected via a first working line and / or via a second working line to the first and / or the second working chamber and at least in one of the two working lines a load-holding valve is provided, through which the working piston of Hydraulic cylinder can be fixed in a certain position. For this purpose, the load-holding valve preferably interrupts the working line in at least one direction, so that a discharge of pressure medium from the first working chamber and / or the second working chamber is prevented.

It is particularly advantageous that at least one load-holding valve can be brought into its open position by using a setting pressure of an adjusting device. The control pressure is for this purpose taken from the adjusting device for adjusting the delivery volume of the first hydraulic pump and the second hydraulic pump. The control of the load-holding valve thus takes place automatically depending on conveying direction.

It is preferably used a pressure-compensated load-holding valve to keep the required operating forces and thus the control pressures low. The set pressures are usually one

Order of magnitude smaller than the achievable working pressures.

According to a further preferred embodiment, the pressure medium reservoir is designed as a hydraulic accumulator. The use of a hydraulic accumulator as pressure medium reservoir allows z. B. recover a portion of the energy expended in operating the hydraulic cylinder, for example, when lifting a load subsequent thereto during the lowering of the load. In addition, such a hydraulic accumulator offers the advantage that the pressure medium stored in it is under a pressure which prevents the possible occurrence of cavitation on the suction side of the hydraulic pump connected thereto. In order to prevent unnecessary pressure loss, the connection between the hydraulic accumulator and the first hydraulic pump is preferably provided with a shut-off valve, which can be acted upon by an actuating pressure of the adjusting device and thus adjustable between its open and closed position. The operation is carried out by Use of the setting pressure again automatically and taking into account the conveying direction.

A particularly compact arrangement results if at least the removal valve and / or the at least one load-holding valve and / or the check valve are arranged in a pump unit which comprises the first and the second hydraulic pump.

Preferred embodiments of the hydrostatic drive according to the invention are shown in the drawing and are explained in more detail in the following description. Show it:

1 shows a first embodiment of a hydrostatic drive according to the invention;

2 shows a second embodiment of a hydrostatic drive according to the invention with load-holding valves.

3 shows a third exemplary embodiment of a hydrostatic drive according to the invention with a hydraulic accumulator as pressure medium reservoir; and

Fig. 4 shows a fourth embodiment of a hydrostatic drive according to the invention with an additional hydraulic accumulator to reduce pressure fluctuations.

The hydrostatic drive 1 shown in Fig. 1 comprises a double-acting hydraulic cylinder 2, in which a working piston 3 is arranged displaceably. The working piston 3 has a first piston surface 4 and a second piston surface 5. The first piston surface 4 and the second piston surface 5 are oriented in the opposite direction. On the side of the second piston surface 5 is the working piston 3 a Piston rod 6 connected. As a result, the second piston surface 5 is smaller than the first piston surface. 4

The first piston surface 4 can be acted upon in a first working chamber 7 of the hydraulic cylinder 2 with a first working pressure acting there. Accordingly, the second piston surface 5 can be acted upon in a second working chamber 8 of the hydraulic cylinder 2 with a second working pressure. The first working chamber 7 is connected to a first working line 9 and the second working chamber 8 is connected to a second working line 10.

For generating volume flows for actuating the hydraulic cylinder 2, a first hydraulic pump 11 and a second hydraulic pump 12 are provided. The first hydraulic pump

11 and the second hydraulic pump 12 are realized according to a preferred embodiment in the form of a double pump, so that the adjustment of the delivery volume of the first hydraulic pump 11 and the hydraulic pump 12 takes place together. The first hydraulic pump 11 and the second hydraulic pump

12 are connected to their respective first port 13 and 14 via the first working line 9 with the first working chamber 7. The first working line 9 branches off to the first and the second hydraulic pump 11, 12 in a first working line branch 9a and a second

Work line branch 9b. The first working line branch 9a is connected to the first connection 13 of the first hydraulic pump 11. Accordingly, the second working line branch 9b is connected to the first connection 14 of the second hydraulic pump 12.

While the first ports 13, 14 of the first hydraulic pump 11 and the second hydraulic pump 12 are connected in parallel to the first working chamber 7, the respective second ports 15, 16 of the first hydraulic pump 11 and the second hydraulic pump 12 are not both connected to the second working chamber 8 , With the second working chamber 8, only the second port 16 of the second hydraulic pump 12 is connected. This results in a closed hydraulic circuit connecting the first working chamber 7 and the second working chamber 8 via the second hydraulic pump 12.

The first working chamber 7, however, is over the first

Working line 9 and the first hydraulic pump 11 additionally arranged in an open circuit. The second connection 15 of the first hydraulic pump 11 can be connected to a tank volume 18 via a suction line 17 for this purpose.

The first hydraulic pump 11 and the second hydraulic pump 12 are driven by a common drive shaft 19 by a drive machine, not shown. To set the first delivery volume of the first hydraulic pump 11 and the second delivery volume of the second hydraulic pump 12, the respective adjustment mechanisms of the first hydraulic pump 11 and the second hydraulic pump 12 are connected to an adjusting device 20. The adjusting device 20 comprises a control cylinder 21, in which an actuating piston 22 is arranged displaceably. Of the

Control piston 22 is acted upon by a first control pressure in a first control pressure chamber 23 of the actuating cylinder 21 and a second control pressure in a second control pressure chamber 24 in the opposite direction. As a result of self-adjusting acting on the actuating piston 22

Force difference, the first hydraulic pump 11 and the second hydraulic pump 12 are changed together in their delivery volume. The set delivery volume of the first hydraulic pump 11 and the second hydraulic pump 12 are always in a fixed predetermined relationship to each other. In the preferred embodiment of the first hydraulic pump 11 and the second hydraulic pump 12 together in the form of a double pump, in particular the delivery volume of the first hydraulic pump 11 is equal to the delivery volume of the second hydraulic pump 12th

To set the first control pressure and the second control pressure in the first control pressure chamber 23 and the second control pressure chamber 24 is a vertical pressure control valve 25 provided. The control pressure control valve 25 is in the illustrated embodiment, a 4/3-way valve, which is centered by a set of springs. From this centered position, in which all four connections of the control pressure control valve 25 are separated from each other, the control pressure control valve 25 can be deflected in the direction of a first end position or in the direction of a second end position by electromagnets. Depending on the setting of the control pressure control valve 25 is a first control pressure line 26 or a second

Stelldruckleitung 27 with a first connecting line 28 or a relaxation line 29 connectable. The first control pressure line 26 is connected to the first control pressure chamber 23. The second control pressure line 27 is connected to the second control pressure chamber 24. Depending on the setting of the control pressure control valve 25, consequently, the first control pressure chamber 23 is acted upon via the first connecting line 28 with a control pressure and the second control pressure chamber 24 via the second control pressure chamber 27 in an inner tank volume 18 'relaxed, which is preferably connected to the tank volume 18. In contrast, the reverse pressure actuation control valve 25, the second actuating pressure chamber 24 is connected to the first connecting line 28 and the first actuating pressure chamber 23 with the expansion line 29.

The maximum available setting pressure is the adjusting pressure control valve 25 in the manner already mentioned via the first connecting line 28, respectively. In addition to the first hydraulic pump 11 and the second hydraulic pump 12, which are preferably designed in the manner already mentioned as a double pump, comprises the thus formed

The feed device 31 is used for Nachfördern leaked by leakage from the circuit pressure medium, and generating an initial pressure at startup of the drive 1. The feed pump 32 is also connected via the drive shaft 19 to the drive machine and is as a constant pump intended to be promoted in one direction only. The feed pump 32 sucks this over a

Feed pump suction 33 pressure medium from the tank volume 18 and conveys it into a feed pressure line 34. To limit the maximum available feed pressure is the feed pressure line 34 by a

Supply pressure limiting valve 35 secured. The feed pressure limiting valve 35 is acted upon in the direction of its closed position by a compression spring.

In the opposite direction, the pressure prevailing in the feed pressure line 34 acts on a measuring surface of the feed pressure limiting valve 35. If the feed pressure in the feed pressure line 34 exceeds a critical value predetermined by the pressure spring, the feed pressure limiting valve 35 is adjusted in the direction of its open position due to the hydrostatic force. In the open position, the feed pressure line 34 is connected via a further expansion line 36 to the inner tank volume 18 '.

The feed pressure line 34 of the feed device 31 is also connected via a first feed line 37 to the first working line 9. Furthermore, the

Supply pressure line 34 is connected via a second feed line 38 to the second working line 10. In the first feed line 37 and in the second feed line 38, a first and second check valve 39, 40 is arranged. The two non-return valves 39, 40 are arranged in the first supply line 37 and the second supply line 38 so that they open in the direction of the first working line 9 and on the second working line 10 back. If the pressure set in the feed device 31 by the feed pressure limiting valve 35 exceeds the pressure in the first working line 9 or in the second working line 10, then pressure medium from the feed device 31 will be in the first Working line 9 and the second working line 10 supplied.

Parallel to the first feed line 37 and the second feed line 38, a second connecting line 41 and a third connecting line 42 is provided. The second connecting line 41 connects the first working line 9 with the feed pressure line 34. A first pressure limiting valve 43 is provided in the second connecting line 41. The first pressure relief valve 43 is biased as the feed pressure relief valve 35 in the direction of its closed position by means of a compression spring. The prevailing in the first working line 9 first working pressure acts in the opposite direction to the first pressure relief valve 43. If the first working pressure exceeds the set by the compression spring maximum pressure, the first pressure relief valve 43 is brought into its open position. In the open position of the

Pressure limiting valve 43, the first working line 9 is connected to the feed pressure line 34. As a result, when a critical pressure in the first working line 9 is exceeded, the first working line 9 is relaxed in the direction of the feed device 31. In the same

In the third connection line 42, a second pressure limiting valve 44 is arranged, which releases the second working line 10 into the feed device 31 when a critical pressure in the second working line 10 is exceeded.

With a displacement of the working piston 3, the resulting volume flows from / into the first and second working chamber 7, 8 in a ratio determined by the ratio of the piston surfaces 4, 5 ratio. Deviates from the ratio of the total delivery volume of the first and second hydraulic pump 11, 12 to the delivery volume of the second hydraulic pump 12 from, so a flow equalization is required. For removing pressure medium from the first or the second working line 9 or 10 for volume flow compensation, a removal valve is provided in the hydrostatic drive 1. In the illustrated, preferred

Embodiment, the removal valve is designed as a purge valve 45. The purge valve 45 is designed as a 3/3-way valve. An output port of the purge valve 45 is connected to the feed pressure line 34. The purge valve 45 is held in its middle position by a first centering spring 48 and a second centering spring 49. The two input ports of the purge valve 45 are connected via a first extraction line 46 and a second extraction line 47 to the first working line 9 and the second working line 10. From the first extraction line 46 branches off a first line branch 50, which acts on a measuring surface on the purge valve 45 to the pressure of the first working line 9. The hydrostatic force generated at the measuring surface by the first working pressure acts in the same direction as the first one

Centering spring on the purge valve 45 and acts on this in the direction of a first switching position.

In the first switching position of the purge valve 45, the second sampling line 47 is connected to the feed pressure line 34. Thus, a flow-through connection is made from the second working line 10 into the feed device 31. The purge valve 45 is constructed symmetrically in the illustrated embodiment. Accordingly, a second line branch 51 is provided, which connects the second removal line 47 with a further measuring surface of the purge valve 45, wherein the second working pressure acting there acts on the purge valve 45 in the same direction with the second centering spring 49. If the resulting force thus generated exceeds the force generated in the opposite direction by the first working pressure and the first centering spring 48, the purge valve 45 is brought into its second switching position. In the second switching position is a flow-through connection between the first extraction line 46 and the feed pressure line 34 made.

For the following embodiments, it is assumed that the first piston surface 4 and the second piston surface 5 are in a relationship to one another, which is slightly smaller than 2. For example, that is

Area ratio of the first piston surface 4 to the second piston surface 5 1.8 to 1.9: 1. Such area ratios are typical of commercially available double-acting

Hydraulic cylinders, such as those used for generating the force on a boom and a stick of an excavator.

Is by the first hydraulic pump 11 and the second

Due to the first working pressure, which is greater than the second working pressure in the second working pressure line 10, the purge valve 45 is under load influence a pressure difference in the first working line 9 and the second working line brought into its first switching position. In the first switching position, the second working line 10 is connected to the feed pressure line 34 in the manner already described. In the described embodiment, a first volume flow V _{7 is} generated in the first working chamber ₇ . From the second working chamber 8, a volume flow of size V ₈ flows out at the same time. The volume flows are in the ratio - = 1.8 to each other. ^8th

Since the two partial volume flows generated by the first hydraulic pump 11 and the second hydraulic pump 12 are the same size, only a partial volume flow of the size 0.9-Vs is sucked in by the first and the second hydraulic pump 11, 12. This results in a delivery side

Total flow of 2-0, 9V ₈ = I, 8V ₈ , which is conveyed into the first working chamber 7. However, since the second working line 10 is connected to the feed pressure line 34 by the purge valve 45, which due to the Oil volume balance required Differenzvolumenstorm (0.1-V ₈ ) are discharged into the feed device 31. The feed device 31 may be connected in a manner not shown with the tank volume 18, which generally serves as a pressure medium reservoir. This is the first one

Connecting line 28 via a compensation line 52 connected to the suction line 17. In the compensation line 52, a check valve 53 is arranged, which opens in the direction of the suction line 17 back.

The ratio of the total delivery volume of the hydraulic pumps 11, 12 to the delivery volume of the second hydraulic pump 12 deviates from the area ratio of the first piston surface 4 to the second piston surface 5. The resulting difference volume flow is discharged via the removal valve, which is designed as a purge valve 45 in the illustrated embodiment. In the case of a delivery in the reverse direction, on the other hand, it results that the pressure medium volume taken from the first working chamber 7 through the first hydraulic pump 11 and the second hydraulic pump 12 is too small in relation to the volume flow flowing into the second working chamber 8. In this case, pressure medium is supplied to the instantaneous suction side of the first hydraulic pump 11 and the second hydraulic pump 12 by the feed pump 32 and the then opening first check valve 39.

A purge valve is generally provided in a closed hydraulic circuit to selectively remove pressure fluid from the circuit. This removed

Pressure medium is replaced by supplied by the feeder 31 pressure medium. The withdrawn pressure medium is cooled before it is returned to the circuit. Through the purge valve 45, the lower pressure leading working line 9 or 10 is connected to the feeder 31. In the illustrated embodiment, the purge valve 45 is a hydraulically actuated 3/3-way valve. The use of a purge valve 45 as a bleed valve allows the connection of any hydraulic cylinder 2. In particular, it is possible because of the symmetry of the purge valve 45, the hydraulic pump unit 30 with any

To operate hydraulic cylinder 2. Thus, the first piston surface 4 in the ratio of z. B. 2.2: 1 to the second Kolbenfäche 5 stand. In this case, the removal or the supply of pressure medium reverses upon actuation of the hydrostatic drive 1. If pressure medium is then conveyed into the first working chamber 7 by the first hydraulic pump 11 and the second hydraulic pump 12, a pressure medium quantity is additionally conveyed into the second working line 10 by the feed pump 32 at an area ratio of 2.2: 1. In the reverse direction, however, pressure medium is discharged through the purge valve 45 from the first working pressure line 9 into the feed device 31 and ultimately into the tank volume 18. By using the flushing valve 45 with its symmetrical connection to the first working line 9 and the second working line 10, a uniform hydraulic pump unit 30 can thus be used, to which any desired hydraulic cylinders 2 can be connected.

FIG. 2 shows a second exemplary embodiment of the hydrostatic drive 1 'according to the invention. The matching with the elements of the first embodiment components are provided with the same reference numerals, so that a further detailed description can be omitted. In contrast to the first exemplary embodiment of FIG. 1, in each case one load-holding valve 55, 56 is provided in the first working line 9 and in the second working line 10. The first load-holding valve 55 is arranged in the first working line 9. Accordingly, the second load-holding valve 56 is arranged in the second working line 10. The two load-holding valves 55, 56 are of identical construction. The first load-holding valve 55 is held by a first biasing spring 57 in its initial position. In the starting position of the first load-holding valve 55, a connection of the first working line 9, which can be flowed through in one direction, is generated. This is achieved by a check valve function of the first load-holding valve 55 in its initial position. If, on the other hand, the first load-holding valve 55 is brought into its second switching position, then a piercing connection in the opposite direction is possible.

The check valve in the initial position of the first load-holding valve 55 opens in the direction of the first working chamber 7 and locks at a directed out of the first working chamber 7 volume flow. The first load-holding valve 55, like the second load-holding valve 56, is pressure-compensated in order to enable the load-holding valves 55, 56 to be adjusted counter to the force of the first and second biasing springs 57, 58. For this purpose, in each case acts on the side of the first working chamber 7 and the second working chamber 8 working pressure both in the same direction with the first and second biasing spring 57, 58 and in the opposite direction to the first and second load-holding valve 55, 56 in the opposite direction pressurized surfaces of the first

However, load holding valve 55 and the second load-holding valve 56 differ, so that a slight adjustment of the load-holding valves 55, 56 in their respective second switching position is possible. For supplying the working pressures of the first working line 9 are first

Compensation lines 59 ', 59' 'provided. Accordingly, second compensation lines 60 ', 60 "are provided on the second load-holding valve 56.

To the first load-holding valve 55 from his

Starting position to bring against the force of the first biasing spring 57 in its second switching position, a first control line 61 is provided. The first control line 61 connects the first load-holding valve 55 with the first control pressure line 26. In the same way, the second control pressure line 27 is connected via a second control line 62 to the second load-holding valve 56.

In the illustrated embodiment, the two load-holding valves 55, 56 are actuated hydraulically. However, it is also possible in an alternative embodiment to electrically control the load-holding valves. The control with a corresponding control signal then takes place in accordance with the control of the control pressure control valve 25th

While in the first embodiment of FIG. 1, the first extraction line 46 and the second extraction line 47 are connected to the first working line 9 and the second working line 10 with respect to the first pressure relief valve 43 and the second pressure relief valve 44 on the oriented to the hydraulic cylinder 2 section , the arrangement in the embodiment of FIG. 2 is reversed. Starting from the hydraulic cylinder 2, the second connecting line 41, the first removal line 46 and the first feed line 37 are connected in series with the first working line 9. The first load-holding valve 55 is arranged between the connection points of the first extraction line 46 and the second connection line 41. The arrangement with respect to the second working line 10 is accordingly.

The modified arrangement is also taken into account by connecting the second and third connecting lines 41, 42 to the feed pressure line 34 via a feed pressure line section 34 'and the first connecting line 28.

By providing the first load-holding valve 55 and the second load-holding valve 56 in the first working line 9 or the second working line 10, it is possible to clamp the working piston 3 hydraulically in any position and thus to prevent an unwanted movement. In the initial positions of the first load-holding valve 55 and the second load-holding valve 56, escape of pressure medium from the first working chambers 7 or the second working chamber 8 is not possible due to the non-return valve arranged in the load-holding valve 55, 56. Once the actuator piston 22 returns to its original position and the

Control pressure chambers 23, 24 are relaxed, is on the first control line 61 and the second control line 62 is no sufficient control pressure to the first load-holding valve 55 and the second load-holding valve 56 to bring the respective load-holding valve 55 and 56 in its open position. If, in contrast, an actuating pressure chamber of the adjusting device 20 is subjected to an actuating pressure, the first load-holding valve 55 will be moved into its second position when the first actuating pressure chamber 23 is acted upon via the first control line 61

Switched position brought and an outflow of pressure medium from the first working chamber 7 is possible. If the adjusting device 20 is acted upon in the opposite direction to produce a reverse conveying direction, then the first load-holding valve 55 returns to its initial position due to the force of the first biasing spring 57. At the same time, the second load-holding valve 56 opens and releases a flow path for the outflow of pressure medium from the second working chamber 8 into the second working line 10.

In purely one-sided applications, for example, the hydraulic lifting of loads, in which in a stationary state an outflow is expected only from one of the two working chambers 7, 8, it is also possible, only a load-holding valve 55 or 56 in the corresponding working line 9, 10th provided. Starting from the second embodiment of FIG. 2, the embodiment of FIG. 3 is extended to the effect that the suction line 17 of the first hydraulic pump 11 is connected to a hydraulic accumulator 63 as a pressure medium reservoir. In the suction line 17 is between the

Hydraulic accumulator 63 and the first hydraulic pump 11 is preferably arranged a check valve 64. The check valve 64 is in turn pressure compensated via third compensation lines 65 ', 65' '. The control of the blocking valve 64 via a third control line 66, which branches off from the second control line 62. The check valve 64 is thus brought in a promotion of pressure medium in the direction of the first working chamber 7 in its open position. In an alternative embodiment, the check valve 64 may be like the two

Load holding valves 55, 56 are also electrically controlled.

The use of a hydraulic accumulator 63, which is embodied, for example, as a hydraulic diaphragm accumulator, has the advantage that when pumping pressure medium from the first working chamber 7 out towards the second working chamber 8, it is not necessary to work only against the counterpressure by the second hydraulic pump 12 , but due to the hydraulic accumulator 63 and by the first hydraulic pump 11 must be promoted against pressure. This improves the uniformity of the load for the first hydraulic pump 11 and the second hydraulic pump 12. In addition, the removal of pressure medium from the first working chamber 7 given the opportunity to part of the energy released, for example, when lowering a load in the form of pressure energy in to store the first hydraulic accumulator 63. In a reversal of the conveying direction, this pressure energy is released, so that only a reduced pressure difference must be generated by the first hydraulic pump 11.

Starting from the embodiment of FIG. 3, a second hydraulic accumulator 67 is provided in FIG. 4. With the second hydraulic accumulator 64, the first connecting line 28 is connected. The second pressure accumulator 67 serves to reduce pressure fluctuations in the feed device 31. Such pressure fluctuations can occur in particular at low speeds of the engine, since the funded by the feed pump 32 pressure fluid quantity is directly related to the speed of the drive machine.

The invention is not limited to the illustrated embodiments. Rather, advantageous combinations of individual features shown in the different embodiments are possible.

Claims

claims

1. Hydrostatic drive with a first hydraulic pump (11) and with a second hydraulic pump (12) and with a double-acting hydraulic cylinder (2) with a working piston (3) having a first working chamber (7) with a first piston surface (4) Working piston (3) and a second working chamber (8) with a second piston surface (5) limited, wherein the first and the second hydraulic pump (11, 12) with their respective first port (13, 14) connected to the first working chamber (7) are, the first hydraulic pump (11) with its second port (15) with a pressure medium reservoir (18, 63) and the second hydraulic pump (12) with its second port (16) connected to the second working chamber (8), characterized the drive comprises an extraction valve (45) for removing pressure medium in a first conveying direction of the hydraulic pumps (11, 12).

2. Hydrostatic drive according to claim 1, characterized in that the ratio of the first piston surface (4) to the second piston surface (5) differs from the ratio of the sum of the delivery volumes of the two hydraulic pumps (11, 12) to the second delivery volume.

3. Hydrostatic drive according to claim 1 or 2, characterized in that the second connection (15) of the first hydraulic pump (11) with a pressure medium reservoir (18, 63) is connected and by the removal valve (45), the first working chamber (7) or the second working chamber (8) with the pressure medium reservoir (18, 63) is connectable.

4. Hydrostatic drive according to one of claims 1 to 3, characterized the removal valve is a flushing valve (45) which connects the first or the second working chamber (7, 8) to the pressure medium reservoir (18, 63) as a function of a working pressure prevailing in the first and second working chambers (7, 8).

5. Hydrostatic drive according to claim 4, characterized in that the flushing valve (45) connects the first or the second working chamber (7, 8) via a feed device (31) with the pressure medium reservoir (18, 63).

6. Hydrostatic drive according to one of claims 1 to

5, characterized in that for volume flow compensation in the reverse direction of the first and the second hydraulic pump (11, 12) a feed pump (32) is provided.

7. Hydrostatic drive according to one of claims 1 to

6, characterized in that the first and the second hydraulic pump (11, 12) are adjustable together in their delivery volume.

8. Hydrostatic drive according to one of claims 1 to 7, characterized in that the first and the second hydraulic pump (11, 12) together form a hydraulic pump unit (30).

9. Hydrostatic drive according to one of claims 1 to 8, characterized in that the removal valve (45) via a first

Working line (9) with the first working chamber (7) and / or via a second working line (10) with the second working chamber (8) is connected and a load-holding valve (55, 56) is provided in at least the first or the second working line (9, 10).

10. Hydrostatic drive according to claim 9, characterized in that the first and the second hydraulic pump (11, 12) can be varied in their delivery volume by means of an adjusting device (20) which can be acted upon by at least a first setting pressure and that the at least one

Load holding valve (55, 56) with the at least one actuating pressure in the opening direction can be acted upon.

11. Hydrostatic drive according to claim 9 or 10, characterized in that the at least one load-holding valve (55, 56) is pressure-compensated.

12. Hydrostatic drive according to one of claims 1 to 11, characterized in that the pressure medium reservoir (18, 63) is a hydraulic accumulator (63).

13. Hydrostatic drive according to claim 12, characterized in that between the hydraulic accumulator (63) and the first hydraulic pump (11) a check valve (64) is arranged, which by a control pressure of an adjusting device (20) can be acted upon.

14. Hydrostatic drive according to one of claims 1 to

13, characterized in that at least the removal valve (45) and / or the at least one load-holding valve (55, 56) and / or the check valve (64) in a hydraulic pump unit (30) comprising the first and second hydraulic pumps (11, 12). are arranged.