EP2307726B1 - Adjustable pump - Google Patents

Description

The invention relates to a variable displacement pump with a cam ring which is adjustable in dependence on the pressure in a first Verstelldruckraum and a second Verstelldruckraum, and with a flow regulator, which is designed as a slide valve with a plurality of control edges having flow control piston which is acted upon by a differential pressure, which prevails before and after a hydraulic resistance in a high-pressure area, and with a pressure valve.

From the European patent application EP 1 801 419 A2 a variable displacement pump with a flow regulator and a pressure valve is known, which is designed as a pressure relief valve.

The US 2002/0085923 A1 , which is considered to be the closest prior art, discloses a variable displacement pump having the features of the preamble of claim 1.

The object of the invention is a variable displacement pump with a cam ring which is adjustable in dependence on the pressure in a first Verstelldruckraum and a second Verstelldruckraum, and with a flow regulator, which is designed as a slide valve with a plurality of control edges having flow control piston, with a differential pressure is applied, which prevails before and after a hydraulic resistance in a high-pressure area, and with a pressure valve, in order to optimize the stability and dynamics of the pressure control.

The object is with a variable displacement pump with a cam ring which is adjustable in dependence on the pressure in a first Verstelldruckraum and a second Verstelldruckraum, and with a flow regulator, which is designed as a slide valve with a plurality of control edges having flow control piston which is acted upon by a differential pressure , which prevails before and after a hydraulic resistance in a high-pressure region, and with a pressure valve, achieved in that the pressure valve is designed as a slide valve with a pressure regulating piston having a pressure control edge and is applied to a pressure control surface with the pressure before or possibly behind the hydraulic resistance in the high-pressure area prevails. The hydraulic resistor is preferably arranged in an output line or delivery line of the variable displacement pump. Thus, the pressure before or optionally behind the hydraulic resistance is the pressure in the outlet line or delivery line of the variable displacement pump. According to a substantial Aspect of the invention, both the flow regulator and the pressure valve are designed as a piston valve or piston valve. Such valves are used in hydraulic controls to regulate high pressures and high volume flows with relatively little effort in a small volume of construction. According to a further aspect of the invention, the pressure valve is not designed directly as a pressure relief valve or pressure relief valve, but as a pressure regulator to regulate the adjustment pressure in one of the Verstelldruckräume depending on the pressure between the working pressure chamber, in particular a pressure kidney, the variable displacement pump and the output line or promotion line prevails. The combination of the two designed as a slide valve regulator ensures that the pumped amount of the variable can be kept largely constant regardless of the pump speed and the load pressure. When a maximum pressure is reached, the pump pressure is regulated via the pressure regulator with the help of the cam ring. This can reduce the power consumption of the pump and avoid the risk of overheating the pump at maximum pressure. In addition, both the amount provided by the variable displacement pump or the volume flow provided by the variable displacement pump and the pressure provided by the variable displacement pump can be varied in a simple manner. The use of two independently operating valve pistons allows the volume and pressure control to be optimized separately, thus satisfying the high requirements regarding control quality and dynamics. In addition, the variable displacement pump according to the invention is compact and inexpensive to produce. The hydraulic resistance is preferably a fixed or constant hydraulic resistance, such as a constant diameter orifice or restrictor.

A preferred embodiment of the variable displacement pump is characterized in that the pressure valve in dependence on the pressure prevailing between the working pressure chamber of the variable displacement and the hydraulic resistance, via the flow regulator with one of the Verstelldruckräume is connectable to regulate the pressure before the hydraulic resistance. According to one essential aspect of the invention, the volume control is isolated from the pressure control or independent, and therefore, the valve components for the flow regulator and the pressure regulator can be optimized independently.

Another preferred embodiment of the variable displacement pump is characterized in that one of the Verstelldruckräume via the flow regulator and an outlet throttle with a Pressure relief space or tank communicates. The outlet throttle allows a pressure reduction in the associated adjustment pressure chamber.

A further preferred embodiment of the variable displacement pump is characterized in that the pressure regulating piston of the pressure valve has exactly one control edge. The equipped with this pressure regulating piston pressure regulator is also referred to as a single edge regulator.

A further preferred embodiment of the variable displacement pump is characterized in that the flow control piston of the flow regulator has exactly two control edges. An equipped with such a flow control piston flow regulator is also referred to as a two-edge controller.

A further preferred embodiment of the variable displacement pump is characterized in that the flow control piston of the flow regulator has four control edges. An equipped with such a flow control piston flow regulator is also referred to as a four-edge regulator.

A further preferred embodiment of the variable displacement pump is characterized in that the flow regulator is combined with the pressure valve so that the pressure upstream of the hydraulic resistance can be regulated independently of the volume flow through the hydraulic resistance via the adjustable lifting ring. The pressure before the hydraulic resistance is the pressure that prevails between the working pressure chamber of the variable displacement pump and the hydraulic resistance. The pressure valve is designed according to an essential aspect of the invention as a pressure regulator, which operates separately from the flow regulator and can be tuned. The invention makes it possible in a simple manner to vary both the volume flow, that is to say the quantity, and the pressure of the variable displacement pump.

Another preferred exemplary embodiment of the variable displacement pump is characterized in that the pressure valve has a pressure connection, in particular a pressure connection groove or a pressure connection bore, which can be acted upon by the pressure between the working pressure chamber of the variable displacement pump and the hydraulic pressure dependent on the position of the pressure control edge Resistance prevails. As long as the pressure does not exceed a predefinable set value, a connection between the pressure connection and the working pressure chamber of the variable displacement pump is through the pressure control edge or one associated piston land on the pressure control piston interrupted. When the pressure exceeds the setpoint, a connection is released from the working pressure chamber of the variable displacement pump via the pressure connection to one of the adjustment pressure chambers.

A further preferred exemplary embodiment of the variable displacement pump is characterized in that the pressure port is connected to a connection port provided on the flow regulator, in particular a connecting groove or connecting bore, which in turn communicates with one of the adjusting pressure chambers. The connection port is preferably in communication with a pressure relief space, such as a tank, via an additional throttle.

Another preferred embodiment of the variable displacement pump is characterized in that the pressure valve is integrated in the flow regulator. This space can be saved.

A further preferred exemplary embodiment of the variable displacement pump is characterized in that the pressure regulating piston can be moved back and forth inside the flow control piston. This provides, among other things, the advantage that the two pistons can be accommodated in a single receiving space or cylinder and connecting lines between the pressure valve and the flow regulator omitted.

A further preferred embodiment of the variable displacement pump is characterized in that the hydraulic resistance is designed as a diaphragm. The hydraulic resistance can also be embodied as a throttle, in particular as a constant throttle. When the volume flow increases due to the hydraulic resistance, there is an increasing pressure difference in front of and behind the hydraulic resistance, which is used to control the volume flow.

A further preferred embodiment of the variable displacement pump is characterized in that a variable throttle is connected in parallel to the hydraulic resistance. The variable throttle is preferably designed as an electric valve, which comprises a particular adjustable throttle for volume flow adjustment.

A further preferred embodiment of the variable displacement pump is characterized in that the pressure regulating piston is biased by a spring whose biasing force is adjustable via an electromagnet. The electromagnet is preferably a proportional magnet. By adjusting the preload force different pressures can be set as setpoints for the pressure regulator.

A further preferred embodiment of the variable displacement pump is characterized in that the pressure valve is pilot-controlled by a pilot valve. The pressure valve can also be controlled directly.

A further preferred embodiment of the variable displacement pump is characterized in that one of the Verstelldruckräume by means of the quantity regulator and / or the pressure valve or the quantity and pressure regulator is acted upon or acted upon by a control pressure. The control pressure is generated by means of the quantity regulator and / or the pressure valve or the quantity and pressure regulator from the differential pressure between the high pressure in the high pressure region and the pressure, in particular low pressure, in the pressure relief space or tank. One of the Verstelldruckräume is connected to the tank or Druckentlastungsrum in connection. The other of the adjustment pressure chambers can be acted upon or acted upon by the control pressure in order to adjust the lifting ring.

Another preferred exemplary embodiment of the variable displacement pump is characterized in that the control pressure is connected via one or the outlet throttle to one or the pressure relief space or tank. The outlet throttle is preferably designed as a constant throttle. In this embodiment, the inlet is regulated in the pressurized with the control pressure Verstelldruckraum. Therefore, this design is also referred to as supply control. The drain from the adjusting pressure chamber acted upon by the control pressure is kept constant via the outlet throttle designed as a constant throttle.

A further preferred embodiment of the variable displacement pump is characterized in that the control pressure is connected via an inlet throttle with the high-pressure region in connection. The inlet throttle is preferably designed as a constant throttle, so that the feed to the flow regulator and / or pressure valve is also constant.

A further preferred embodiment of the variable displacement pump is characterized in that the control pressure via the flow regulator and / or the pressure valve or the flow and pressure regulator with one or the pressure relief space or tank is connected or is in communication. In this embodiment, the sequence is regulated from the pressure applied to the control pressure chamber. Therefore, this embodiment is also referred to as sequence control.

A further preferred embodiment of the variable displacement pump is characterized in that the variable displacement pump is designed as a vane pump with a rotor having radially extending vane slots, which serve to guide wings, which are extendable radially outward from the vane slots in the direction of a stroke contour, the the adjustable cam ring is provided. The variable displacement pump according to the invention is preferably used to suck in a hydraulic medium, in particular hydraulic oil from a tank to pressurize and to promote at least one consumer. The consumer is, for example, a power steering device of a motor vehicle.

Figur 1

einen Hydraulikschaltplan einer erfindungsgemäßen Verstellpumpe mit einem Einkanten-Druckregler und einem Zweikanten-Mengenregler;

Figur 2

ein ähnliches Ausführungsbeispiel wie in Figur 1 mit einer zusätzlichen, variablen Drossel;

Figur 3

ein ähnliches Ausführungsbeispiel wie in Figur 1 mit einem Druckregler, dessen Federvorspannkraft verstellbar ist;

Figur 4

ein ähnliches Ausführungsbeispiel wie in Figur 1, in welchem die Ausführungsbeispiele der Figuren 2 und 3 miteinander kombiniert sind;

Figur 5

ein ähnliches Ausführungsbeispiel wie in Figur 1, wobei der Druckregler einen Druckregelkolben umfasst, der in einem Mengenregelkolben des Mengenreglers hin und her bewegbar ist;

Figur 6

ein ähnliches Ausführungsbeispiel wie in Figur 5 mit einer zusätzlichen, variablen Drossel;

Figur 7

ein ähnliches Ausführungsbeispiel wie in Figur 1 mit einem Pilotventil zur Vorsteuerung des Druckreglers;

Figur 8

ein ähnliches Ausführungsbeispiel wie in Figur 5 mit einem Pilotventil zur Vorsteuerung des Druckreglers und die

Figuren 9 bis 16

ähnliche Ausführungsbeispiele wie in den Figuren 1 bis 8 mit einer Ablaufregelung.

Further advantages, features and details of the invention will become apparent from the following description in which, with reference to the drawings, various embodiments are described in detail. The same or similar parts are provided with the same reference numerals. Show it:

FIG. 1

a hydraulic circuit diagram of a variable displacement pump according to the invention with a single-edge pressure regulator and a two-edge flow regulator;

FIG. 2

a similar embodiment as in FIG. 1 with an additional, variable throttle;

FIG. 3

a similar embodiment as in FIG. 1 with a pressure regulator whose spring biasing force is adjustable;

FIG. 4

a similar embodiment as in FIG. 1 in which the embodiments of the Figures 2 and 3 combined with each other;

FIG. 5

a similar embodiment as in FIG. 1 wherein the pressure regulator comprises a pressure control piston which is reciprocable in a flow control piston of the flow regulator;

FIG. 6

a similar embodiment as in FIG. 5 with an additional, variable throttle;

FIG. 7

a similar embodiment as in FIG. 1 with a pilot valve for precontrol of the pressure regulator;

FIG. 8

a similar embodiment as in FIG. 5 with a pilot valve for pilot control of the pressure regulator and the

FIGS. 9 to 16

similar embodiments as in the FIGS. 1 to 8 with a sequence control.

In the FIGS. 1 to 8 is a variable displacement pump 1 with an only indicated pump housing 2 shown in cross-section and simplified with a rotor 4 within a hydraulic circuit diagram. The rotor 4 is driven by a drive shaft 5 counterclockwise, as indicated by an arrow.

In the variable displacement pump 1 is preferably a hydraulic pump, which is designed as a vane pump. In the rotor 4 radially extending slots 6 are provided, in which wings 8 are guided in the radial direction. The wings 8 bear with their radially outer ends to a Hubkontur 9, which is provided on the inside of a cam ring 10. The cam ring 10 of the vane pump is adjustable, slidably or pivotably arranged in the pump housing 2 to vary the flow rate of the vane pump. Therefore, the vane pump is also referred to as a variable displacement pump.

The cam ring 10 of the variable displacement pump 1 is limited within the pump housing 2 two Verstelldruckräume 11, 12, which are separated by sealing means 14, 15 from each other. On the right side of the cam 10 is an actuating piston 18, which is biased by an actuating piston spring 19 which is biased in an actuating piston receiving space 20. By the preload force the adjusting piston spring 19, the cam ring 10 is held with its left side in abutment against a stop surface 16 which is provided on the pump housing 2.

The variable displacement pump 1 comprises a suction kidney 21 and a pressure kidney 22, both of which are indicated by dashed lines. The suction kidney 21 communicates with a pressure relief space or tank 24, which contains hydraulic medium, in particular hydraulic oil. When the rotor 4 of the variable displacement pump rotates in the direction of the arrow, that is to say counterclockwise, an increase in volume occurs in the region of the suction kidney 21, which causes the hydraulic medium to be drawn from the tank 24. At the same time, in the region of the compressed kidney 22, there is a decrease in volume which causes the working medium to be conveyed into a delivery line or outlet line 25 of the variable displacement pump 1, which leads to a consumer, as indicated by an arrow 26.

The region of the variable displacement pump 1 with the pressure kidney 22 is also referred to as the working pressure chamber 22. The working pressure chamber 22 is connected via a hydraulic line 27 to the delivery line 25 in connection. The lines described in the context of the present invention may be embodied as separate lines or as channels which extend through housing parts of the variable displacement pump. In the delivery line 25, a hydraulic resistor 28 is provided between the working pressure chamber 22 and the consumer 26, which is designed for example as a diaphragm or as a constant throttle. The working pressure chamber 22 is also connected via the hydraulic line 27 and a further hydraulic line 29 with the actuating piston receiving chamber 20 in connection.

The right Verstelldruckraum 12 of the variable displacement pump 1 communicates with the tank 24 and the suction kidney 21 in connection. In the illustrated embodiments, the pressure in the actuator piston receiving space 20 and the biasing force of the actuator piston spring 19 ensures that the cam ring 10 is initially held in contact with the stop surface 16. When the pressure in the left Verstelldruckraum 11 increases, then the cam ring 10 moves from left to right or pivots about a pivot axis, which is arranged in the vicinity of the seal 15. By such a displacement or such a pivoting of the cam ring 10, the stroke volume of the variable displacement pump 1 can be reduced from a maximum displacement to a minimum displacement. For this purpose, the pressure in the Verstelldruckräumen 11, 12 as a function of the delivered volume flow and the differential pressure regulated, which prevails in front of or behind the hydraulic resistance 28 in the delivery line or output line 25.

In the in the FIGS. 1 to 4 and 7 illustrated embodiments, the pressure in the Verstelldruckraum 11 is controlled by means of a flow regulator 30 which comprises a flow control piston 31 which defines a space 32 with one of its ends. At the other end of the flow control piston 31 engages a spring 33. The spring 33 is clamped so that the flow control piston 31 is biased in the illustrated closed position. At the flow control piston 31, a collar 34 is provided, which is also referred to as a piston land. The collar 34 has a left control edge 35 and a right control edge 36. Because of the two control edges 35, 36, the flow regulator 30 is also referred to as a two-edge flow regulator.

The flow regulator 30 has in the region of the collar 34 a connection connection 38, which communicates with a pressure connection 39 of a pressure regulator 40. The space 32 of the quantity regulator 30 is connected via a hydraulic line 41 to the delivery line 25 in connection. The associated branching point is arranged between the working pressure chamber 22 and the hydraulic resistor 28. Another hydraulic line 42 connects a spring chamber 43, in which the spring 33 is arranged, at a further branch point, which is arranged behind the hydraulic resistor 28, likewise with the delivery line 25.

The flow regulator 30 comprises a further connection 44, in which a further collar or piston web is arranged, which is formed on the flow control piston 31. The port 44 is connected to the tank 24. Between the two terminals 38 and 44 opens a further connecting line, which is equipped with a small throttle, in the flow regulator 30. The further connecting line with the small throttle is also connected to the tank 24.

At its end facing the spring 33, the flow control piston 31 has a further collar 47. The further collar 47 defines an annular space communicating with the tank 24 via a connecting line 45. Via another connecting line 46, the annular space communicates with a spring chamber 49 of the pressure regulator 40. In the spring chamber 49, a spring 48 of the pressure regulator 40 is biased. The spring chamber 49 is above a Compensation line 50 with an annular space 51 in connection, which is bounded at the spring 48 remote from the end of a pressure regulating piston 52 by a piston pin 54.

The piston pin 54 is non-positively connected to the pressure regulating piston 52 and limited with its free end a pressure chamber 56 which is acted upon via a hydraulic line 57 with the pressure in front of or behind the hydraulic resistor 28. With the same pressure, a further pressure chamber 58 is acted upon, which is designed as an annulus. The annular space 58 extends between a collar 59, from which the piston pin 54 extends, and a further collar 60, which is also referred to as a piston web. At the collar 60, a pressure control edge 61 is formed. Since the pressure control edge 61 is the only control edge of the pressure regulating piston 52, the pressure regulator 40 is also referred to as a single-edge pressure regulator. The pressure control edge 61 is simultaneously inlet edge for the adjustment pressure in the Verstelldruckraum 11. An outlet throttle 62 allows a pressure reduction in the Verstelldruckraum 11. The outlet throttle 62 creates a throttled connection between the annulus of the flow regulator 30 and the tank 24th

The pressure regulating piston 52 is located in the FIGS. 1 to 4 and 7 in its closed position, in which a connection between the annular space 58 and the pressure port 39 is interrupted by the collar 60 with the control edge 61. When the pressure control piston 52 moves to the right due to a pressure increase in the pressure chamber 56 against the biasing force of the spring 48, the connection between the annular space 58 and the Druckanschlussnut 39 is released from the pressure control edge 61, so that hydraulic medium from the annular space 58 via the pressure port 39th and the connection terminal 38 of the flow regulator 30 in the Verstelldruckraum 11 passes.

An increase in the pressure in the left Verstelldruckraum 11 ensures that the cam 10 is moved against the piston 18 and the spring 19 from left to right. As a result, the flow rate or the displacement of the variable displacement pump 1 is reduced. Reducing the flow rate leads to a decrease in the differential pressure at the hydraulic resistance 28. This ensures that the flow control piston is pushed by the force of the spring 43 from right to left. The control edge 36 on the collar 34 now releases the connection between the connection port 38 and the annular space adjacent to the control edge 36 of the piston 31, so that the connection port 38 is connected via the annular space with the outlet throttle 62 and the port 44. By further displacement of the flow control piston 31 to the left interrupts the middle collar of the piston 31, the connection between the annular space of the piston 31 and the port 44. The annular space of the piston 31 is now connected only by the outlet throttle 62 to the tank 24. As soon as before or after the hydraulic resistance 28, a maximum pressure value, which is set by the spring biasing force of the spring 48, falls below, the pressure control piston 52 shifts by the biasing force of the spring 48 back to the left, so that the connection between the annular space 58 and the Druckanschlussnut 39 is closed again by the collar 60 with the pressure control edge 61.

The flow regulator 30 operates independently of the pressure regulator 40. As the volume flow in the delivery line 25 increases, the pressure in front of the hydraulic resistor 28 increases. The resulting pressure difference acts between the space 32 and the spring chamber 43 of the flow regulator 30. Due to the increasing pressure in front of the hydraulic resistor 28 of the flow control piston 31 is moved against the biasing force of the spring 33 to the right until the control edge 35 on the collar 34 a Releases connection between the space 32 and the connection terminal 38, so that hydraulic medium from the room 32 passes into the Verstelldruckraum 11. In this case, the right control edge 36 of the collar 34 closes a connection between the tank 24 and the left Verstelldruckraum 11. The increasing pressure in the Verstelldruckraum 11 allows the cam ring 10 pivot back so far until the desired flow rate corresponding to the pressure difference at the hydraulic resistance 28 is established. As soon as the volume flow in the delivery line 25 or the resulting pressure difference decreases, the flow control piston 31 moves back to its illustrated closed position.

At the in FIG. 2 illustrated embodiment is in contrast to the in FIG. 1 illustrated embodiment, a variable throttle 68 connected in parallel to the hydraulic resistor 28. The variable throttle is designed as electrically controlled 2/2-way valve with a closed position and a throttle position. The variable throttle 68 creates a bypass past the hydraulic resistor 28 in its throttle position. As a result, depending on demand, in addition to the hydraulic resistance 28, by which the variable displacement pump 1 adjusts to a constant volume flow, a larger volume flow can be adjusted.

At the in FIG. 3 illustrated embodiment, the biasing force of the spring 48 can be varied by a spring piston 70 which engages in the spring chamber 49 on the spring 48. The spring piston 70 is limited by an electromagnet 71 in the axial direction displaced. The electromagnet 71 is preferably designed as a proportional magnet and is driven via an electrical amplifier 72. When the spring actuator piston 70 is moved toward the pressure regulating piston 52 by means of the electromagnet 71, the spring 48 in the spring chamber 49 between the pressure control piston 52 and the spring actuator piston 70 is further compressed so that the associated spring biasing force increases. Similarly, the spring biasing force can be reduced by the spring piston 70 is moved by means of the electromagnet 71 of the pressure regulating piston 52 away.

At the in FIG. 4 Embodiment shown are in the Figures 2 and 3 illustrated embodiments combined. On the one hand, a variable restrictor 68 is connected in parallel to the hydraulic resistor 28 in order to enable a volume flow adjustment in a simple manner. In addition, the biasing force of a spring 48 of the pressure regulator 40 by means of an electromagnet 71, which is driven by an electric booster 72, are adjusted via the spring piston 70 to vary the maximum pressure of the variable displacement pump 1.

At the in FIG. 7 illustrated embodiment is in contrast to the in FIG. 1 illustrated embodiment in the connecting line 46 between the pressure regulator 40 and the flow regulator 30, a pilot valve 75 is arranged, which comprises a prestressed spring. The pilot valve opens only when the pressure in the spring chamber 49 exceeds a predetermined by the biasing force of the spring of the pilot valve 75 value. The spring chamber 49 is above the compensation line 50, in which in FIG. 7 illustrated embodiment, an additional throttle 76 is provided, connected to a pressure chamber 77 which is bounded by the spring 48 remote from the end of the pressure regulating piston 52. The in the FIGS. 1 to 4 shown piston pin 54 is in the in FIG. 7 illustrated embodiment does not exist. The pressure chamber 77 is acted upon by the pressure before or after or behind the hydraulic resistor 28. The pressure regulator 40 operates at the in FIG. 7 illustrated embodiment, only when the spring biasing force of the pilot valve 75 is overcome by the pressure in the spring chamber 49.

In the FIGS. 5, 6 and 8th Embodiments are shown with a combined flow and pressure regulator 80, in which a flow regulator, as described above, and a pressure regulator, as described above, are combined in a particularly compact design.

The flow regulator comprises a flow control piston 81, which is acted upon at one end with the biasing force of a spring 82. On the flow control piston 81, two control edges 84, 85 are provided, which are arranged in the region of a terminal 86. The connection 86 is connected via a connecting line 88 with the left Verstelldruckraum 11 of the variable displacement pump 1 in connection. The spring 82 remote from the end of the flow control piston 81 is acted upon via a hydraulic line 91 with the pressure prevailing between the working pressure chamber 22 of the variable displacement pump 1 and the hydraulic resistor 28. Via a further hydraulic line 92, the spring chamber, in which the spring 82 is arranged, communicates with the delivery line 25.

The hydraulic resistance 28 is arranged between the branch points of the hydraulic lines 91, 92 in the delivery line 25. The pressure regulator of the combined quantity and pressure regulator 80 comprises a pressure control piston 95, which is received in the flow control piston 81 movable back and forth. One end of the pressure control piston 95 is acted upon by the biasing force of a spring 96 which is biased in the flow control piston 81 against the associated end of the pressure regulating piston 95. At its end facing away from the spring 96, the pressure control piston 95 has a piston pin 98, which is acted upon in a pressure chamber 99 with the pressure in front of the hydraulic resistor 28.

The port 86 is in the pressure control via a throttle bore or outlet throttle 100, the outlet throttle 62 in FIG. 1 corresponds and has the same function as this, with an annular space in the interior of the flow control piston 81 in conjunction. The annular space is connected via a central bore with a spring chamber in connection, in which the spring 96 of the pressure regulating piston 95 is arranged. Via a further bore 97 is a ring-like pressure chamber within the flow control piston 81 with a space 94 outside of the spring 82 opposite end of the flow control piston 81 in connection. The space 94 is acted upon by the hydraulic line 91 with the pressure in front of the hydraulic resistor 28. The inner annular pressure chamber, which is assigned to the pressure regulator, is closed by a control edge 101 of the pressure regulating piston 95.

When the pressure regulating piston 95 moves to the right with increasing pressure in the pressure chamber 99 against the spring force of the spring 96 in the flow control piston 81, the control edge 101 is a connection between the inner annular pressure space, which is also referred to as inner annulus, and the terminal 86 free, so that hydraulic medium from the inner annular space via the terminal 86 and the connecting line 88 enters the left Verstelldruckraum 11. Since the pressure regulating piston 95 has only one control edge 101, the pressure regulator is also referred to as a single-edge pressure regulator. Similarly, the flow regulator with the flow control piston 81 with its two control edges 84, 85 referred to as a two-edge flow regulator.

Via a further bore 102 in the flow control piston 81, the spring chamber, in which the spring 96 is arranged, communicates with an annular space 103, which communicates with the tank 24. This connection allows the escape or compensation of hydraulic medium from the interior of the flow control piston 81 when the pressure regulating piston 95 moves in the flow control piston 81. The flow regulator with the flow control piston 81, which has the two control edges 84 and 85, works in principle as well as in the FIGS. 1 to 4 and 7 It is essential that the two control pistons 81 and 95 have separate control edges and operate independently of each other, although the pressure regulating piston 95 is reciprocably received in the flow control piston 81 back and forth.

At the in FIG. 6 illustrated embodiment is in contrast to the in FIG. 5 illustrated embodiment, a variable throttle 108 connected in parallel to the hydraulic resistor 28. The variable throttle 108 has the same function as the variable throttle 68 already described in FIGS Figures 2 and 3 , Therefore, to avoid repetition, the preceding description of the Figures 2 and 3 directed.

At the in FIG. 8 illustrated embodiment is in contrast to the embodiments of the FIGS. 5 and 6 a pilot valve 115 upstream of the pressure regulator of the combined quantity and pressure regulator 80. The pilot valve 115 is arranged in a connecting line 110, which connects the annular space 103 with the tank 24. The pilot valve 115 has the same function as that in FIG FIG. 7 Therefore, to avoid repetition, the previous description of the FIG. 7 directed.

In the in the FIGS. 1 to 8 illustrated embodiments, the Verstelldruckraum 11 of the variable displacement pump 1 via the connection terminal 38 of the pressure regulator 40 and the outgoing of the combined quantity and pressure regulator 80 connecting line 88 can be acted upon with a control pressure. The control pressure is via the outlet throttle 62; 100 relieved in the tank 24. The outlet throttle 62; 100 is designed as a constant throttle. Thus, in the in the FIGS. 1 to 8 illustrated embodiments of the inlet regulated in the acted upon by the control pressure Verstelldruckraum 11. This control is also referred to as supply control for the control pressure of the variable displacement pump 1. Figures 9 to 16 show similar embodiments as in the FIGS. 1 to 8 , which, however, are equipped with a flow control instead of an inlet control. In the sequence control, the inflow of the control pressure is kept constant, while the flow of the control pressure to the tank 24 is regulated down, so the flow is regulated.

In the in the FIGS. 9 to 16 illustrated embodiments, the adjustment pressure chamber 12 of the variable displacement pump 1 via the pressure port 39 of the pressure regulator 40 and the connection port 116 of the flow regulator 30 or one of the combined flow and pressure regulator 80 outgoing connection line 117 can be acted upon with the control pressure. The control piston spring 19 is also acted upon via the Verstelldruckraum 12 with the control pressure. In contrast to the preceding embodiments, however, the actuating piston is not combined with the actuating piston spring 19. An actuating piston 118 is arranged on the actuating piston spring 19 opposite side of the cam ring 10. The actuating piston 118 protrudes into the Verstelldruckraum 11 and is connected on its side remote from the cam ring 10 with the high-pressure region, that is acted upon by the delivery pressure of the variable displacement pump 1. The adjustment pressure chamber 11 is connected via the connecting line 88 with the tank 24 in connection.

About a designed as a constant throttle inlet throttle 120, the inflow of the control pressure in the Verstelldruckraum 12 with in the FIGS. 9 to 16 illustrated embodiments held constant. The flow of the control pressure is controlled by a control edge of the flow control piston 31; 81 to the tank 24 down regulated.

The control pressure acts in the in the FIGS. 9 to 16 illustrated embodiments on Druckwirkflächen on the right side of the ring ring 10 in the Verstelldruckraum 12. The left side of the ring ring 10 is in the Verstelldruckraum 11 always with the tank pressure acted upon and can only be pressed by the additional high-pressure actuator piston 118 in the zero stroke position. Otherwise, the components have the same reference numerals as in the FIGS. 1 to 8 are provided in the in the FIGS. 9 to 16 illustrated embodiments, the same function as described above. <B><u> REFERENCE LIST </ u></b> 1 variable 132 room 2 pump housing 33 feather 4 rotor 34 Federation 5 drive shaft 35 control edge 6 slots 36 control edge 8th wing 38 connection port 9 raising contour 39 pressure connection 10 lifting ring 40 pressure regulator 11 Verstelldruckraum 41 hydraulic line 12 Verstelldruckraum 42 hydraulic line 14 sealing device 43 feather 15 sealing device 44 connection 16 stop surface 45 connecting line 18 actuating piston 46 connecting line 19 Adjusting piston spring 47 Federation 20 Adjusting piston receiving space 48 feather 21 suction kidney 49 spring chamber 22 pressure kidney 50 compensation line 24 tank 51 annulus 25 delivery line 52 Pressure control piston 26 arrow 54 piston pin 27 hydraulic line 56 pressure chamber 28 Hydraulic resistance 57 hydraulic line 29 connecting line 58 annulus 30 flow regulator 59 Federation 31 Flow control piston 60 Federation 61 control edge 116 connection port 62 outlet throttle 117 connecting line 68 variable throttle 118 actuating piston 70 Spring adjusting piston 120 inlet throttle 71 electromagnet 72 electrical amplifier 75 pilot valve 76 throttle 77 pressure chamber 80 Volume and pressure regulator 81 Flow control piston 82 feather 84 control edge 85 control edge 86 connection 88 connecting line 91 hydraulic line 92 hydraulic line 94 pressure chamber 95 Pressure control piston 96 feather 97 drilling 98 piston pin 99 pressure chamber 100 outlet throttle 101 control edge 102 drilling 103 annulus 108 variable throttle 110 connecting line 115 pilot valve

Claims (13)

1. Adjustable pump having a cam ring (10) which can be adjusted in a manner dependent on the pressure in a first adjusting pressure space (11) and a second adjusting pressure space (12), and having a quantity controller (30) which is configured as a slide valve with a quantity control piston (31; 81) which has a plurality of control edges (35, 36; 84, 85) and is loaded with a differential pressure which prevails upstream and downstream of a hydraulic resistance (28) in a high pressure region, and having a pressure valve (40), the pressure valve (40) being configured as a slide valve with a pressure control piston (52; 95) which has a pressure control edge (61; 101) and is loaded on a pressure control face with the pressure upstream or possibly downstream of the hydraulic resistance (28), the pressure valve being integrated into the quantity controller, characterized in that the pressure control piston (95) can be moved to and fro within the quantity control piston (81).
2. Adjustable pump according to Claim 1, characterized in that one of the adjusting pressure spaces (11, 12) is connected via the quantity controller (30; 80) and an outflow throttle (62; 100) to a pressure relief space or tank (24).
3. Adjustable pump according to either of the preceding claims, characterized in that the pressure control piston (52; 95) of the pressure valve (40) has precisely one control edge (61; 101).
4. Adjustable pump according to one of Claims 1 to 3, characterized in that the quantity control piston (31; 81) of the quantity controller (30) has precisely two control edges (35, 36; 84, 85).
5. Adjustable pump according to one of Claims 1 to 3, characterized in that the quantity control piston of the quantity controller has four control edges.
6. Adjustable pump according to one of the preceding claims, characterized in that the hydraulic resistance (28) is configured as an orifice plate.
7. Adjustable pump according to Claim 6, characterized in that a variable throttle (68; 108) is connected in parallel to the hydraulic resistance (28).
8. Adjustable pump according to one of the preceding claims, characterized in that the pressure value (40) is pilot-controlled by way of a pilot valve (75; 115).
9. Adjustable pump according to one of the preceding claims, characterized in that one of the adjusting pressure spaces (11; 12) can be loaded or is loaded with a control pressure with the aid of the quantity controller (30) and/or the pressure valve (40) or the quantity and pressure controller (80).
10. Adjustable pump according to Claim 9, characterized in that the control pressure is connected via a or the outflow throttle (62; 100) to a or the pressure relief space or tank (24).
11. Adjustable pump according to Claim 9, characterized in that the control pressure is connected via an inflow throttle (120) to the high pressure region.
12. Adjustable pump according to Claim 11, characterized in that me control pressure can be connected or is connected via the quantity controller (30) and/or the pressure valve (40) or the quantity and pressure controller (80) to a or the pressure relief space or tank (24).
13. Adjustable pump according to one of the preceding claims, characterized in that the adjustable pump (1) is configured as a vane cell pump with a rotor (4) which has radially running vane slots (6) which serve to guide vanes (8) which can be extended radially to the outside out of the vane slots (6) in the direction of a cam contour (9) which is provided on the adjustable cam ring (10).

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