EP2602492A2 - Electro-hydraulic control device - Google Patents

Abstract

The device (1) has a valve arrangement (16) comprising valves e.g. seat valves and slider valves. A position transducer (46) senses a position of an actuator element and generates a position signal to be applied to a controller. The controller comprises an input to receive the position signal and an output to predefine a pressure medium quantity to a pressure medium source. The controller comprises a logic circuit that supplies a pulsed actuation signal or a predefined actuation signal to outflow valves (34, 38) or an actuation signal or a predefined actuation signal to the source. The pressure medium source is designed as an adjustment pump or a rotational-speed-controlled constant pump (2).

Description

The invention relates to an electro-hydraulic control device according to the preamble of claim 1.

In the WO 02/086 327 A1 an electro-hydraulic control device is shown, which is designed as a "digital hydraulic", ie as a digital servo valve circuit. Such a control device has a plurality of parallel and digitally switchable seat valves, by which an opening cross-section of the digital servo valve circuit is basically set in stages. It is also known to control such poppet valves pulsed, so that intermediate values between the open and the closed position can be realized over the time average.

Instead of such digital hydraulic proportional valves are used in the usual way, which are controlled by a controller to move an actuator, such as a hydraulic cylinder. Such proportional valves are suitable for infinitely accelerating or braking the actuator, so that a dynamic speed adjustment of the actuator is made possible. For fine positioning of the actuator, however, a considerable device and control engineering effort is required in solutions with proportionally adjustable valves.

Although this disadvantage can be overcome with the above-mentioned digital hydraulic problematic is that the control via a digital hydraulic actuators with different volumes of oil, for example in a differential cylinder, also requires a lot of effort to an adjustment with the required dynamics cause. Another disadvantage of digital hydraulics is the Noise development of the pulsed switching valves and the associated wear of these components.

In contrast, the invention has for its object to provide an electro-hydraulic control device by which a speed control or position control with low device and control engineering effort is possible.

This object is achieved by an electro-hydraulic control device with the features of claim 1.

Advantageous developments of the invention are the subject of the dependent claims.

According to the inventive concept, the control of an actuator during the speed control takes place essentially via a variable-volume pressure medium source, while the positioning is carried out essentially via a digital hydraulic system.

Specifically, an electrohydraulic control device according to the invention has a valve arrangement, via which pressure medium connections of an actuator, for example a hydraulic cylinder or a hydraulic motor, can be connected to a pressure medium source or a tank. This valve arrangement has a plurality of valves with switching characteristic, which are controlled pulsed via a controller. According to the concept of the invention, the pressure medium source is designed variable in volume and the valve arrangement is designed such that at least two terminals of the actuator in each case a drain valve is associated. Via such a drain valve, a fluid connection between the relevant port and the tank is controlled.

According to the invention, the controller has a setpoint input to which a setpoint signal for a speed and / or a position of the actuator can be fed. Furthermore, the controller is associated with a position transducer for detecting a position of the actuator whose position signal is supplied to an input of the controller. This also has an output for specifying a pressure medium quantity to the pressure medium source, wherein the controller forms an actuating signal from the signal at the setpoint input and the position signal. This essentially corresponds to a speed specification of the hydraulic consumer / actuator.

According to the concept of the invention, the controller has a logic circuit which supplies at least one drain valve either a pulsed drive signal formed from the control signal or a predetermined drive signal and which supplies the pressure medium source with either a drive signal formed from the control signal or a predetermined drive signal. By means of this circuit, it is possible, for example, initially to move the actuator by suitable control of the pressure medium source at the predetermined speed and then to control the approach via the logic circuit when approaching the predetermined desired position, that the drain valve is driven pulsed via the predetermined drive signal.

In one embodiment of the invention, the logic circuit is designed such that at least one drain valve, a predetermined drive signal is supplied and the pressure medium source, the drive signal formed from the control signal is supplied.

In an alternative solution, the logic circuit is adapted to supply the pressure medium source with a predetermined drive signal, while supplying at least one drain valve, formed from the control signal, preferably pulsed, drive signal.

In a further alternative it is provided that the logic circuit is designed such that it supplies the pressure medium source with a predetermined drive signal, while supplying at least one inlet valve, a pulsed drive signal formed from the control signal.

In an advantageous variant of the control device is provided that each port of the actuator or the consumer is associated with an inlet valve which controls a fluid connection between this port and the pressure medium source.

Such a control device and such a method for driving a control device allow an adjustment of an actuator with a high dynamic and when switching to the control via the digital hydraulic exact positioning, the advantages of the above-mentioned prior art are combined and the disadvantages, ie a high noise during the speed control and a complicated position control over proportionally adjustable elements are overcome.

In one embodiment of the invention, the acceleration and the speed control is carried out essentially by the control of the pressure medium source and the position control and possible braking operations of the actuator essentially by driving the valve assembly (digital hydraulic), which of course also mixed forms with control of the pressure medium source and simultaneous control of the digital hydraulic possible are.

The valves of the valve assembly are preferably designed as switchable seat or slide valves, as for example in the WO 02/086324 A1 are described.

In one embodiment of the invention, the valve assembly is arranged with a plurality of switching valves in a common valve housing.

In a preferred embodiment, the valves of the valve assembly behave ballistically, ie the valve piston opens in short pulses without reaching its upper end position and then falls back on the valve seat. For longer switch-on pulses, the valve piston reaches its upper end position and falls back after a short dwell time. This corresponds approximately to a pulse width modulation of the opening cross-section or of the averaged fluidic flow. With even longer switch-on periods, the valve may behave inversely ballistic, ie the piston then falls back only briefly in the direction of the seat during the switch-off time, but does not reach it anymore. Such a ballistic operation is for example from the DE 102 24 689 A1 known, so that further explanations are dispensable.

In a variant of the invention, the actuator is designed as a hydraulic cylinder with two pressure chambers, which are each connected via one of the inlet valves to the pressure medium source and one of the drain valves with a tank or a return.

The pressure medium source can be configured, for example, as a variable displacement pump or as a variable-speed fixed displacement pump.

The control of the valves of the valve assembly can be done after a pulse width modulation (PWM). The pulse width modulation can be carried out at a frequency which is 0.5 to 1.0 times the maximum switching frequency of the respective valve.

In one embodiment, the pressure medium source is designed with a subordinate volume flow control loop or with a subordinate pressure control loop.

In another embodiment of the invention, pressure transducers are used to detect the pressures at the actuator ports and at the pump outlet. The signals from these pressure transducers are reported to the corresponding actual value inputs of the controller.

Via a position transducer, the position of the actuator can be detected.

• Figur 1 ein Schaltschema einer erfindungsgemäßen Steuereinrichtung und einer Variante einer derartigen Steuereinrichtung und
• Figur 2 ein Diagramm zur Verdeutlichung des erfindungsgemäßen Regelungskonzeptes.

Preferred embodiments of the invention are explained in more detail below with reference to schematic drawings. Show it:

• FIG. 1 a circuit diagram of a control device according to the invention and a variant of such a control device and
• FIG. 2 a diagram to illustrate the control concept of the invention.

As shown in FIG. 1 an electro-hydraulic control device 1 according to the invention has a pressure medium source, in the present case a variable speed constant pump 2, the motor 4 is speed controlled via a speed controller 6 to regulate a pressure medium flow, so that a consumer, in the present case, a hydraulic cylinder 8 is movable at a predetermined speed , As long as this hydraulic cylinder 8 is moved at a constant speed, the pressure at the pressure connection of the pump can also be regulated via the speed regulator 6. That is, the pump 2 is pressure / flow regulated.

The control of the speed controller 6 via a controller, hereinafter referred to as motion controller 10, via the speed controller 6 according to the target values for the position s _soll and / or velocity v _soll of the hydraulic cylinder 8 or the pressure p _to the pump is driven. These setpoint values are calculated, for example, as a function of a speed preset, which is set, for example, via a joystick or the like.

Corresponding to these setpoint values, a pressure medium volume flow requirement Q _{5 is} output by the motion controller 10 to the speed controller 6 as a setpoint and via this a corresponding speed of the motor 4 and thus a delivery volume flow of the pump 2 are adjusted.

The hydraulic cylinder 8 has a piston rod-side annular space 12 and a bottom-side annular space 14, which are connected via a dash-dotted line indicated valve assembly 16 to the pressure port of the pump 2 or a tank T. The electro-hydraulic control device 1 is thus designed as an open circuit. The valve assembly 16 may be combined in a single housing to form a structural unit.

Each pressure chamber 12, 14 is connected via a working line 18 or 20 with a working port A, B of the valve assembly 16, which in turn are in fluid communication with two line sections, which are referred to below as inlet 22 and outlet 24, wherein depending on the switching position of Valve assembly 16 of the "inlet 22" also as a drain and the "drain 24" can serve as an inlet accordingly. In the inlet 22, an inlet valve 26 is arranged, which is designed in the illustrated embodiment as a 2/2-way valve in slide construction. In principle, this switching valve can also be designed as a seat valve.

The inlet of the inlet valve 26 is then connected to a connected to the pressure port of the pump 2 pump line 29. A branch of this pump line 28 is connected to the inlet of a further inlet valve 28, the output terminal is connected to a supply line 30, which opens into the drain 24. The two valves 26, 28 are identical.

From the inlet 22 branches off downstream (in pressure build-up direction) from a drain line 32 which is connected to the input port of a further 2/2-way valve, which is referred to below as a drain valve 34. Its output terminal is connected to a tank line 36. A branch of this tank line 36 is connected to the output of another drain valve 38, whose input terminal is connected to the drain 24.

The two drain valves 34, 38 are designed as 2/2-way valves with switching characteristic. These switching valves can be actuated electrically or electro-hydraulically and are as shown in FIG FIG. 1 biased by a spring, not shown in the de-energized state in its locked position.

According to the above statements, each pressure chamber 12, 14 is thus assigned an inlet valve 26, 28 and a drain valve 34, 38.

These switching valves are switchable with high dynamics and designed for use with digital hydraulics. You can do this with a so-called "booster" valve amplifier for faster switching. Such valves are known from the prior art, so that further explanations are unnecessary. The switching of the valves takes place via the motion controller 10, corresponding to the actual position s of a piston rod 40 of the hydraulic cylinder 8 and the desired desired position s _soll a control signal Q ₁ , Q ₂ , Q ₃ , Q ₄ to the switching valves 26, 34, 28, 38 is delivered to their adjustment. The control of these valves takes place after a pulse width modulation (longer switch-on pulses) or with smaller switch-on pulses such that the valve piston does not reach its upper end position (opening) (ballistic behavior). To realize such a ballistic behavior, the motion controller 10 is designed with a device for generating control pulses of variable duration, wherein this period of time is such that a thus actuated valve of the valve assembly from the closed position performs an opening stroke, but without reaching its complete switched open position falls back into the closed position or wherein the time duration of the control pulses is such that a thus actuated valve of the valve assembly from its fully open position performs a closing stroke, but is switched back to the open position without reaching the full closed position (inverse ballistic).

About two pressure transducers 41, 42, the pressure in the working lines 18, 20 is detected. A third pressure sensor 44 serves to detect the pressure in the pump line 29.

The signal of these pressure sensors 41, 42, 44 is reported to the motion controller 10 via a corresponding signal line as actual values P, Pa and Pb.

The stroke s of the piston rod 40 is detected by a displacement transducer 46 and - as explained - reported as an actual position s to the motion controller 10.

The motion controller 10 has a logic circuit, not shown, via which, for example, from the target value for the position and / or the speed of the actuator and the position sensor detected via the position sensor 46, a control signal is formed, which then essentially the speed specification of the hydraulic cylinder 8 and whose piston rod 40 corresponds. The pressure medium source is then driven in response to the control signal formed from the control signal or via a predetermined drive signal. For example, when approaching a desired position or when starting the consumer, the pressure medium source can be controlled in response to a predetermined Ansteursignal, while the respective drain or inlet valve is driven pulsed in response to a control signal formed from the control signal. In simple words, it is decided via the logic circuit, depending on the state of movement or the position of the respective hydraulic consumer, whether the pump 2 or an inlet or outlet valve is controlled to move the consumer at the predetermined speed or in the range of the predetermined position , The respective other switching element (pressure medium source or inlet / outlet valve is then driven according to a predetermined control signal.) For example, the drain valve during the control of the pressure medium source can be completely opened, in reverse, the pressure medium source can be operated under pressure control pulsed control of the drain / inlet valve become.

The pressure medium source can be designed with a subordinate volume flow control loop and / or with a subordinate pressure control loop.

The control concept according to the invention will be described with reference to the diagram in FIG FIG. 2 explained.

FIG. 2 above shows the desired stroke s of the piston rod 40 over time t. Accordingly, a comparatively short stroke s should be kept constant during a first time interval t ₁ . Within a time interval t ₁ -t ₂ , the piston rod 40 should then be extended at a constant speed to a stroke s ₂ and then held in this position.

In the two diagrams below this lift curve, the control behavior of the valve assembly 16 and below the control behavior of the pump 2 is shown.

Accordingly s ₁ is used to hold the first stroke in time interval t ₁ through the logic circuit of the motion controller 10, the valve assembly is driven 16 with the respective active inlet valve 26 or 28 and the drain valve according lying in the effluent in each case 34 or 38 so as to adjust the position of the piston rod 40 to hold. During this position control via the valve arrangement 16 (digital hydraulic), the described pressure regulation of the pump 2 is active.

To extend the piston rod 40 to the stroke s ₂ , the valves in the inlet and in the flow are completely controlled by the logic circuit and controlled by the motion controller 10, the flow rate of the pump 2, so that the piston rod 40 extends at the predetermined speed.

Upon reaching the desired position s ₂ , the pump 2 is in turn switched to pressure control and the position / speed control of the piston rod via the digital hydraulic with the valve assembly 16 made. That is to move to the desired position s ₂ and for holding the target position of the valves 26, 28, 34, 38 of the valve assembly are controlled by a pulse width modulation and / or after a ballistic behavior 16, so that the target position is maintained with great precision.

In FIG. 1 is explained with the below-dash-dotted box a variant of the embodiment described above. In this case, a variable displacement pump 2 is used instead of a variable speed pump 2, wherein the pressure / flow control via a pump regulator 48 takes place, for example, adjusts a pivot angle of a swash plate of an axial piston pump. The motor 4 of this pump can be constant Speed can be operated. Even with such a variant can be based on FIG. 2 realize explained control behavior.

Disclosed is an electro-hydraulic control device and a method for controlling such an electro-hydraulic control device, wherein, for example, a speed control via a volume-adjustable pressure medium source and a position control via a digital hydraulic system.

LIST OF REFERENCE NUMBERS

1

control device

2

pump

4

engine

6

Speed governor

8th

hydraulic cylinders

10

Motion Controller

12

annulus

14

pressure chamber

16

valve assembly

18

working line

20

working line

22

Intake

24

procedure

26

inlet valve

28

inlet valve

29

pump line

30

supply line

32

drain line

34

drain valve

36

tank line

38

drain valve

40

piston rod

41

Pressure transducer

42

Pressure transducer

44

Pressure transducer

46

transducer

48

pump regulator

Claims (15)

Electrohydraulic control device for actuating an actuator of a hydraulic consumer with a plurality of pressure medium connections, which can be connected via a valve arrangement (16) with a pressure medium source or a tank (T), wherein the valve arrangement (16) has valves with switching characteristic, which are driven pulsed via a controller wherein the pressure medium source is designed volume adjustable, and wherein the valve assembly (16) is formed such that each port at least one drain valve (34, 38) is associated, which controls a fluid connection between this port and the tank, wherein the controller with a setpoint input is designed for the speed and / or the position of the actuator, wherein a position transducer (46) is provided for detecting the position of the actuator whose position signal is applied to an input of the controller having an output for specifying a pressure medium quantity to the pressure medium source and wherein the controller from the signal at the setpoint input and the position signal forms an actuating signal which substantially corresponds to a speed specification of the hydraulic consumer, wherein the controller comprises a logic circuit, the at least one drain valve (34, 38) either one formed from the control signal pulsed Control signal or a predetermined drive signal feeds, and the pressure medium source either supplies a control signal formed from the control signal or a predetermined drive signal. Control device according to claim 1, wherein the logic circuit is adapted to supply at least one drain valve (34, 38) a predetermined drive signal while supplying the pressure medium source, the drive signal formed from the control signal. Control device according to claim 1, wherein the logic circuit is adapted to supply the pressure medium source with a predetermined drive signal, while supplying at least one drain valve, a pulsed drive signal formed from the actuating signal. Control device according to claim 1, wherein the logic circuit is adapted to supply the pressure medium source with a predetermined drive signal, while supplying at least one inlet valve, a pulsed drive signal formed from the control signal. Control device according to one of the preceding claims, wherein the Ventilanodnung is formed such that each port is associated with an inlet valve which controls a fluid connection between this port and the pressure medium source. Control device according to one of the preceding claims, wherein an acceleration and speed control and optionally a pressure control substantially by controlling the pressure medium source and the position control and braking operations are controlled by controlling the valve assembly (16) substantially. Control device according to one of the preceding claims, wherein the valves of the valve arrangement (16) seat or slide valves. Control device according to one of the preceding claims, wherein the valve arrangement is arranged in a common valve housing. Control device according to one of the preceding claims, wherein the control of the valves of the valve assembly (16) after a pulse width modulation (PWM) takes place. Control device according to one of the preceding claims, wherein the valves of the valve arrangement (16) are ballistically controllable. Control device according to one of the preceding claims, wherein the actuator is a hydraulic cylinder (8) with two pressure chambers (12, 14) each with one of the inlet valves (26, 28) with the pressure medium source and one of the drain valves (34, 38) with the Tank (T) are connectable. Control device according to one of the preceding claims, wherein the pressure medium source is designed as a variable displacement pump (2) or as a variable-speed fixed displacement pump (2). Control device according to one of the preceding claims, with pressure sensors (41, 42, 44) for detecting the pressure at the outlet of the pressure medium source or on the actuator. Control device according to claim 13, wherein the pressure medium source is volume flow and pressure controlled. Control device according to one of the preceding claims, wherein the pressure medium source has a subordinate volume flow control loop and / or has a subordinate pressure control loop.

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