EP1350033A2 - Device for the force oil feed of a hydraulic consumer operated at a defined operating pressure p b? - Google Patents

Abstract

A pressure feed system has a first pump (41) permanently loading a pressure accumulator (52) used as a source of pressure for a hydraulic cylinder (11). A second pump (42) feeds a cooling circuit operating in a low power mode. A reservoir-loading configuration (RLC) (41,42,59) loads a reservoir up to a specific pressure when the reservoir pressure falls below a threshold value. The RLC has a switch valve to switch the second pump to a mode for reservoir loading.

Description

Device for supplying pressure oil to a hydraulic consumer operated with a defined operating pressure p _B

description

The invention relates to a device for supplying pressurized oil to a hydraulic consumer operated with a defined operating pressure p _B , in the operation of which a significant leakage oil flow occurs, which is returned to the reservoir of a pressure supply unit, and with the further generic features mentioned in the preamble of claim 1.

In a device of the type mentioned initially designed by the applicant and used in large quantities for use in machining centers, the pressure supply unit comprises a first one, permanently in the sense of charging a pressure source for the consumer, e.g. For example, a hydraulic clamping cylinder of a clamping device for a rotatably drivable workpiece that can be subjected to turning, a pressure accumulator used, and a second pump that feeds a cooling circuit in an almost inefficient circulation mode, in which hydraulic oil from the reservoir via an oil cooler back to the reservoir of the pressure supply unit is directed. The purpose of this oil cooling is to limit the temperature of the hydraulic oil to a value linked to a viscosity of the hydraulic oil that is suitable for the operation of the consumer, at which a leakage oil flow, which may be caused by a rotating union, via which the consumer is supplied with pressurized oil , can be kept within a limited range of values so that the first pump used to charge the pressure accumulator does not have to be designed for a disproportionately high peak delivery rate. Furthermore, a storage charging device controlled by a pressure monitoring device is provided, by means of which, after a if the storage pressure falls below a threshold value p _S u the storage can be recharged to a pressure p _s which is significantly higher than the operating pressure used in the consumer, which, for. B. is adjustable by means of a pressure control valve assigned to the consumer. The pressure supply unit also serves for the short-term supply of pressure oil to at least one other hydraulic consumer, eg. B. one of the turning station, which includes the clamping cylinder, assigned tool changer, with which various tools provided for the machining of the workpiece can be delivered to the processing station, the - relatively short-term - pressure oil requirement of such an additional consumer, based on the unit of time, being significantly higher can be that of the consumer to be operated with a defined operating pressure p _B , the operating pressure p _B of which should be largely constant over the turning machining time in order to ensure good machining quality of the workpiece.

So that the temporarily significantly increased pressure oil requirement can be covered, the pump, which operates permanently in the sense of charging the pressure accumulator, is designed as a swash plate axial piston pump, the delivery volume of which can be changed automatically per revolution of the rotor.

The known device has at least the following disadvantages due to its structural and functional properties explained so far:

The need to set the - first - pump charging the accumulator to an increased delivery rate takes a relatively large amount because of the masses to be accelerated, be it in terms of increasing the rotor speed of the pump or adjusting the swash plate against restoring forces exerted by the pump pistons Time required, with the result that in cases in which a tool change is required several times during the machining of the workpiece, this is necessary total time consumed is comparable to the time that the workpiece is subjected to machining. This is disadvantageous in terms of production technology, since the total time required for the tool change should, if possible, be significantly smaller than the total time required for machining the workpiece.

Associated with this is also disadvantageous that the pump permanently charging the accumulator must be designed for a relatively large maximum delivery rate in order to be able to supply a sufficiently high delivery rate for a reasonably short changeover time in tool changing operation. The construction costs and space requirements associated with the storage tank charging pump are therefore relatively high and are associated with correspondingly high costs.

The object of the invention is therefore to improve a device of the type mentioned in such a way that with a simpler and less expensive construction of the same, a significant reduction in the time periods within which the need-based pressure oil supply can be achieved is achieved.

This object is achieved by the characterizing features of claim 1. In this way, at least the following advantages are achieved.

Because the pump, which is normally used for cooling, is already working in the delivery mode when it is switched to the storage tank charging mode, its full delivery rate is immediately available for charging the pressure accumulator, so that, apart from the switching time of the changeover valve, there are some is a few milliseconds, there is practically no delay in the charging operation and the time required to recharge the memory is minimized. The first pump delivering permanently into the pressure accumulator can be designed for a comparatively low delivery rate, which only has to be sufficient to compensate for the leakage oil flow caused by the assigned consumer and to keep the accumulator pressure within a limited range at an average value p _s that it is sufficient to derive the operating pressure p _{B of} the consumer from this. The pump that permanently pumps into the reservoir can therefore be designed as a relatively small and correspondingly inexpensive constant pump.

Since the periods of time in which the pump, which is normally used for cooling, is used as a storage tank charging pump, the delivery capacity of which is added to that of the pump that is permanently in charging operation, can be kept very short, the cooling effect is not noticeably impaired and, despite the reduction in, the overall structural effort, in particular with regard to the pump that is permanently operating in the loading mode, a significant reduction in the store loading times in relation to the machining times required for machining a workpiece.

In a preferred embodiment of the device according to the invention, the pump which feeds the cooling circuit and which is normally in almost no-load circulating operation is designed for a delivery rate which corresponds to twice or three times the amount of the delivery rate of the pump operating permanently in charging mode.

The features of claim 3 provide an advantageous design of a pressure control valve designed as a store loading valve, which provides a quick and reliable switchover of the pump that normally feeds the cooling circuit to its store loading operation. Under conditions in which a switching of the second pump, which feeds the cooling circuit during normal operation of the device, should not take place, or at most very rarely, should take place during a machining process, in particular a fine turning process, it is particularly expedient if, in accordance with the preferred design of the device, an electronic or Electromechanical pressure sensor is provided which generates a characteristic for the pressure prevailing in the pressure accumulator electrical output signal, so that at least the first pump z. B. can be controlled by means of an electronic control unit processing the output signals of the pressure sensor according to the features of claim 4. A subsequent control of the delivery rate of the pump is expediently carried out so that a once increased increase in delivery rate is maintained until the pressure value is reached again, at which the pressure limitation of the pressure supply unit, for. B. by the response of a pressure relief valve, what z. B. is recognizable from the output signals of the pressure sensor and a subsequent possible reduction in the delivery rate of the "pressure-controlled" pump takes place in small steps only to such an extent that the storage pressure remains only slightly below the response value of the pressure limitation and in any case is kept above that value is, in which the second pump would also be switched to the storage charging mode.

If the delivery rate of the first pump, which is permanently operating in charging mode, is increased, it is generally also expedient to increase the delivery rate of the second pump feeding the cooling circuit in the same direction, since a consequent improvement in the cooling effect of the cooling circuit in the sense of an increase or Reducing the decrease in the viscosity of the pressurized oil has an effect and, as a result, reduces the need for an increased oil feed into the consumer circuit. For the purpose of the simple design of the pressure supply unit and the simple controllability of the two pumps of the same, these are designed in a preferred design as constant pumps which have a common drive motor with a controllable or adjustable speed.

As an alternative or in addition to a change in the delivery capacity of the first pump operating permanently in the store charging mode and / or of the second pump feeding the cooling circuit as a function of detected pressure values in the consumer circuit, it is also advantageous if a temperature sensor is provided, the output signals of which control the Delivery capacity of the pressure supply unit can be used according to the features of claim 7.

In the case of a use of the device according to the invention for pressurized oil supply to a hydraulic clamping cylinder of a lathe, it is of particular importance that accumulator loading processes, which take place using the second pump, do not take place within the time periods in which a fine machining of the respective workpiece takes place because otherwise pressure fluctuations in the clamping cylinder caused by loading processes can lead to minor changes in the clamping forces in the clamping device and thus to visible "traces" - irregular spots - of the workpiece surface being machined.

In such an application, it is therefore particularly important to exhaust all possibilities of keeping the operating pressure constant before a storage tank charging process is triggered using the pump feeding the cooling circuit and is therefore expedient if the pressure oil supply device is equipped with a sensor system according to the features of claim 9, whereby a temperature sensor of this sensor system expediently to control the cooling capacity of an oil cooler, most simply by Control of the cooling air delivery capacity of a cooling fan is used, which offers a further possibility to keep the viscosity of the pressure oil relatively high by cooling and thus to counteract pressure drops in the consumer circuit.

To achieve a good cooling effect, it can also be advantageous to direct an output oil flow from the pressure limiting valve of the pressure supply unit directly to the oil cooler, as provided in claim 11.

Further details of the invention result from the following description of a special embodiment shown in the drawing. Show it:

1 shows a schematically simplified electrohydraulic circuit diagram of a device according to the invention for supplying pressure oil to a hydraulic cylinder provided for actuating a clamping device of a lathe, which is connected to the pressure supply unit of the hydraulic unit via a rotary leadthrough;

FIG. 2 shows details of a storage loading valve of the device according to FIG. 1.

For the pressure oil supply device designated as a whole in FIG. 1 for the purpose of explanation only, ie without restricting generality, it is assumed that a double-acting, linear hydraulic cylinder 11 is provided as the hydraulic consumer, e.g. B. the clamping cylinder of a hydraulic clamping device 12 of a lathe represented by it, otherwise not shown, this clamping device direction 12 on the one hand a tensioning of a z. B. round rod-shaped workpiece 13 "from the outside" or, on the other hand, clamping a z. B. tubular workpiece 14 "from the inside", and these alternative clamping functions of the clamping device 12 alternative directions of the deflections of the tubular work spindle 16 on a portion of its length surrounding the outside of the cylinder housing 17 relative to a spindle-fixed piston flange 18 are assigned by the Within the cylinder housing 17, two annular pressure spaces 19 and 21 are delimited against each other in a pressure-tight manner, by means of their alternative pressurization and relief, the direction of the deflection of the cylinder housing 17 can be predetermined and the type of workpiece clamping can thus be selected.

To select the type of clamping suitable for the workpiece, which is to be achieved by means of the clamping device, a function control valve, designated as a four-two-way solenoid valve and designated as a whole with 22 and with latched function positions I and II, is provided, which by alternative excitation of two control windings 23 and 24 of switching magnets can be switched from the previously assumed switching positions I and II to the alternative switching positions II and I, respectively.

In one switch position I of the function control valve 22, its operating pressure (p _B ) connection 27 is connected to the A consumer connection 28 and the T return connection 29 is connected to the B consumer connection 31 of the function control valve 22. In the other functional position II of the function control valve 22, its p _B supply connection is connected to the B consumer connection 31 and the T return connection 29, from which a return line 26 leads "directly" to the unpressurized reservoir 32 of the pressure supply unit, generally designated 33, with which A consumer port 28 of the function control valve 22 connected. The consumer connections 28 and 31 of the function control valve 22 are individually assigned via a rotary feedthrough provided on the tensioning cylinder 11, generally designated 34, and the pressure chambers 19 and 21 of the tensioning cylinder 11, which can be integrated into the housing 17 thereof or can be permanently attached to the latter and can be securely mounted thereon hydraulically connected to one of the pressure chambers 19 or 21. The two non-return valves 36 and 37 are controlled in their open position when the operating pressure p _B is present at one of the consumer connections 28 or 31 of the function control valve 22, but reach when the operating pressure drops, ie when the supply connection 27 of the function control valve at p _B current pressure drops into its blocking position, so that pressure oil cannot flow out of the pressure chambers 19 and 21 of the tensioning cylinder 11 and the tensioning function of the tensioning device 12 is maintained at least for a safety period.

To specify the operating pressure p _B , which, depending on the selected clamping mode, is to be coupled into one or the other pressure chamber 19 or 21 of the clamping cylinder 11 in order to develop the required clamping force of the clamping device 12, a clamping pressure specification valve 38 is provided, which is located between the pressure outlet 39 of the pressure supply unit 33 and the p _B supply connection 27 of the function control valve 22 is connected.

The pressure supply unit 33 comprises two (high) pressure pumps 41 and 42 which are connected to the pressure outlet 39 of the pressure supply unit 33 via these individually assigned pressure oil filters 77 and 78 and downstream check valves 43 and 44.

The two pumps 41 and 42 have a common, electrically controlled drive motor 48 and are therefore in operation as long as it is activated. The pumps 41 and 42 are designed as constant pumps. det whose flow rates Q] and Q _{2 are} different based on the speed of the drive motor 48.

The output pressure level of the pressure supply unit 33 is by means of a pressure relief valve 49, which is connected between the pressure outlet 39 of the pressure supply unit 33 and its non-pressurized reservoir 32, to a value p _Max of z, which can be predetermined by setting the preload of a valve spring 51 of the pressure relief valve. B. 90 bar limited.

A pressure accumulator 52 is connected to the pressure outlet 39 of the pressure supply unit 33 and, in the event of a malfunction of the pressure supply unit 33, can be used as an "auxiliary" pressure source for a time-limited "safety" mode, within which the working mode of a processing machine equipped with the clamping cylinder 11 can be used can be switched off without the risk that the workpiece 13 or 14 does not remain securely clamped until the work spindle 16 comes to a standstill.

This pressure accumulator 52 is dimensioned so that the storage content is sufficient, within the safety period, a pressure drop in the respective pressure chamber 19 or 21 of the clamping cylinder, which is caused by a leakage oil flow, which via the leakage oil line 53 originating from the rotary union 34 to the reservoir 32 of the pressure supply unit 33 is derived to be able to compensate sufficiently for so long, d. H. to be able to ensure the fixed clamping of the workpiece by means of the clamping device 12 until the drive spindle 16 is braked to a standstill.

The delivery rate Qi of one pump 41 related to the speed of the drive motor 48 and the delivery rate Q _{2 of} the other which is correlated with it Pump 42 of the pressure supply unit 33 are in a special design of the pressure oil supply device 10 in a ratio of 1: 3 to each other.

Between the pressure outlet 54 of the "larger" pump 42 designed for the larger delivery quantity Q ₂ and its outlet check valve 44 branches off from the outlet path 56 of this pump 42 via an oil cooler 57 leading back to the reservoir 32, generally designated 58, which can be released and, if necessary, shut off by means of a pressure-controlled changeover valve 59, which conveys the function of an accumulator charging valve.

The pressure supply unit 33 of the pressure oil supply device 10 is also provided for the pressure oil supply to a further, only schematically indicated, consumer 61, which is connected via a (high) pressure supply line 62 to the pressure outlet 39 of the pressure supply unit 33 and either via a separate return line or one with the return line 26 the return line branch 26 'connected to the pressure oil supply device 10 and to the unpressurized reservoir 32 of the pressure supply unit 33 via a separate leak oil line branch 53' or connected to the leak oil line 53.

The clamping pressure specification valve 38 is designed in such a way that the operating pressure p _B provided at the operating pressure connection 27 of the function control valve 22 can be adjusted within a wide range by - manual or motor-controlled - adjustment of the bias of its valve spring 65, e.g. B. between 10% and 90% of the output pressure p _A provided at the pressure outlet 39 of the pressure supply unit, which also corresponds to the pressure of the pressure oil stored in the pressure accumulator 52. This adjustability enables the need-based adjustment of the means the clamping device 12 on the respective workpiece 13 or 14 clamping forces to be achieved on the stability of the workpiece.

The changeover valve 59 used as a store loading valve is designed such that, starting from an operating situation in which the outlet pressure p _A present at the pressure outlet 39 of the pressure supply unit is greater than an upper changeover threshold value p _S o, the z. B. is 2 to 3% lower than the maximum outlet pressure of the pressure supply unit 33, which corresponds to the value given by the pressure relief valve 49, assumes its flow position in which the pump 42, which is larger in terms of the delivery rate, in the oil cooling, almost powerless Recirculation mode works, in the event that the outlet pressure p _{A falls} to a lower changeover threshold p _S u, which is about 10 to 15% lower than the maximum outlet pressure of the pressure supply unit, reaches its blocking position, in which the larger pump 42 contributes via its output check valve 44 to the pressure supply of the tensioning cylinder 11 and mediates the recharge of the pressure accumulator 52, and, as soon as the output pressure p _A has risen again to the upper switching threshold value p _S o, switches back to its flow position in which the output oil flow is larger feed pump is returned to the oil cooler 57 and the larger oil pump 42 again operates in circulation.

Reference is now made to FIG. 2 for a more detailed explanation of the accumulator charging valve 59 with regard to its basic structure and its function. The accumulator loading valve 59 comprises a switching valve unit, generally designated 59/1, and a control unit, generally designated 59/2. The changeover valve unit 59/1 comprises a cylindrical pot-shaped changeover piston 81, which is displaceably guided in a pressure-tight manner in a housing bore 82 and in this housing bore a connection space 83 to which the pressure outlet 54 of the "Larger" pump 42 is connected, delimited from a control chamber 84, which in turn communicates with a control chamber 86 of the control unit 59/2. The connection chamber 83 communicates with the control chamber 84 via a throttle bore 87 arranged on the bottom of the pot-shaped piston 81, which in turn communicates with the control chamber 86 of the control unit 59/2 via a correspondingly designed throttle bore 88.

The control chamber is delimited on the housing side by two coaxial bores 91 and 92 adjoining one another via a radial shoulder 89. In the bore 91, which is larger in diameter, a control piston 93 is displaceably guided in a pressure-tight manner and also forms the axially movable boundary of a pressure sensor chamber 94, into which the pressure p _A prevailing at the pressure outlet 39 or in the accumulator 52 is coupled. The annular transition edge 96 between the smaller bore step 92 and a conical extension to a bore step 97 of larger diameter forms a valve seat for a valve ball 98 which is urged against the valve seat 96 by a valve spring 99 with adjustable spring force F _f . The relief chamber 101 containing the valve spring 99 is connected to the reservoir 32 via a drain line 105.

The cross-sectional area A1 of the smaller bore step 92 that can be covered by the valve ball 48 is smaller than the cross-sectional area A2 of the larger bore 91 of the control unit 59/2 which is blocked off by the cylindrical control piston 93. The control piston 93 is supported on the valve ball 98 via a slim plunger 106.

To explain the function of the accumulator charging valve 59, which has a special design in this respect, a situation in which the pressure oil supply device 10 is started up is assumed, in which the valve ball 98 is pressed onto the seat 96 in a sealing manner and the piston 81 of the switching valve unit 59/1 is pushed by a weak return spring 102 into the blocking position of the valve, in which the connection space 83 against the output channel 103, to the z. B. the cooler 57 is connected according to FIG. 1, is shut off. As the pressure p _A at the outlet 39 increases, which essentially also corresponds to the pressure coupled into the control chamber 84 of the changeover valve unit 59/1 and into the control chamber 86 of the control unit 59/2, the pressure-related forces acting on the control piston 93 become initially balanced.

The ball seat valve 96, 98 of the control unit 59/2 opens as soon as the force resulting from the valve ball 98 being exposed to the pressure p _A on an effective area A1 is greater than the set preload of the spring 99. With the opening thereof Ball seat valve relieves the pressure on the control chamber 86 towards the reservoir 32, as does the piston 81 of the changeover valve unit 59/1, the piston of which reaches the open position of the changeover valve unit 59/1 against the restoring force of the weak return spring 102.

Due to the difference between the areas A1 and A2, the pressure p _S u at which the control unit 59/2 returns to the blocking state of its ball seat valve, corresponding to the area ratio ^ IA _{2, is} lower than the value p _S o at which the ball seat valve 96/98 opens due to the pressure coupled into the control chamber 86.

To explain the function of the pressure oil supply device 10, which has now been described in terms of its construction, it is assumed that the function control valve 22 moves into its intended flow mode, associated flow, e.g. B. the functional position I, switched t, furthermore the pressure space ^ of the clamping cylinder 1 J to be acted upon for this purpose and the Pfjypk accumulator 52 still depressurized ^ swrcl, accordingly the accumulator loading valve 59 assumes the blocked position and the tightening process is initiated by switching on the drive motor 48 of the two pumps 41 and 42.

In this assumed initial state of the pressure oil supply device 10, the drive motor of the drive spindle 16 (not shown) must not be able to be activated, since the clamping device 12 does not yet develop any clamping force.

To detect this state, an electronic or electromechanical pressure sensor 64 is provided, which generates an electrical output signal characteristic of the accumulator pressure or the pressure p _A prevailing at the pressure outlet 39 of the pressure supply unit 33. This output signal is fed to an electronic control unit 66, which is shown only schematically and is provided for operating control of the pressure oil supply device 10. B manual activation, the drive motor 48 of the two pumps 41 and 42 is first switched on, both of which work in this initial phase of the tensioning operation in the sense of a rapid build-up of pressure in the pressure space 21 of the tensioning cylinder 11 used for fixed tensioning and for a correspondingly rapid charging of the pressure accumulator 52.

In this introductory "tensioning" operating phase of the pressure oil supply device 10, the upper switching threshold value pso, at which the switching valve 59 automatically switches the larger pump 42 to circulation mode under pressure control, is usually reached after a short time, which the electronic control unit 66 uses on the basis of time processing - "Observation" - the output signal of the pressure sensor 64 recognizes.

In the further operation of the pressure oil supply device 10, the electronic control unit 66 mediates the switching on of the drive motor of the work spindle 16 and further functions, the following explanation of which sufficient for the description of the electronic circuitry of the electronic control unit can be viewed, the implementation of which can be expected from a specialist in electrohydraulic circuitry with knowledge of these functions based on current specialist knowledge.

Such functions are more specifically the following:

If the pressure p _s in the pressure accumulator 52 drops with a moderate rate of change in the course of a longer machining of the workpiece 13 or 14, the electronic control unit 66 reacts to this by actuating the pump drive motor 48 in the sense of increasing the motor speed and thus the delivery capacity of the two pumps 41 and 42. This increases the cooling effect by increasing the oil flow which is passed through the circulation flow path 58 through the cooler 57, with the result that a leakage oil flow flowing through the leakage oil line 53 to the reservoir 32 is reduced and the pressure in the pressure accumulator 52 rises again, ultimately with the result that pressure fluctuations in the pressure space 21 or 19 of the clamping cylinder 11 used for the clamping operation are largely avoided.

As further inputs, which are processed by the electronic control unit according to plausibility criteria into control signals for the drive motor 48 of the pumps 41 and 42, by means of which the drive motor 48 is controlled in such a way that the changeover valve 59 switches from cooling operation of the larger pump 42 to largely avoid pressure generation operation thereof, the electronic control unit 66 is supplied on the one hand with the electrical output signal of the electronic temperature sensor 67, which is a measure of the temperature in the reservoir 32 of the pressure supply unit 33, and on the other hand with an electrical speed signal, which is a measure for the speed v at which the drive spindle 16 is rotatory is driven. The temperature-characteristic output signal of the temperature sensor 67 is an indirect measure of the viscosity of the pressure oil with which the hydraulic consumer 1 is operated; the speed-characteristic input signal of the electronic control unit 66, which, depending on the type of drive motor, the drive spindle 16 can be obtained from its control or can be generated by means of a speed sensor 68 which directly detects the speed of the drive spindle 16, is an indirect measure of the thermal load on the pressure oil used to operate the consumer and, in this respect, a measure of the probability that significant leakage oil flows occur which can lead to a pressure drop in the consumer.

If the temperature in the reservoir 32 of the pressure supply unit 33, which is detected by means of the temperature sensor 67, rises without an appreciable pressure drop occurring simultaneously in the pressure accumulator 52, i. H. If the delivery rate of the smaller pump 41 is sufficient to cover the pressure oil requirement of the tensioning cylinder 11, the electronic control unit generates an output signal which increases the speed of an electric drive motor 69 and thus the air delivery rate of a cooling fan 71, which is only indicated schematically and which generates a cooling air flow. which is directed to the oil cooler 57 designed as an oil-to-air heat exchanger.

This type of temperature monitoring of the pressure oil circulating in the device 10 is expedient in the event that the clamping device is operated with relatively low clamping forces, ie comparatively low pressure in the pressure chamber 19 or 21 of the clamping cylinder 11 used in each case, but the work spindle 16 is driven at high speed is, so that, due to the internal friction in the pressure oil, a considerable temperature increase can occur, however, the leakage oil flow remains comparatively low due to the relatively small pressure drop between the drive pressure chamber of the tensioning cylinder 11 and the reservoir 32. This type of oil temperature control is also useful in the event that the device 10 for supplying pressure oil to another consumer 71, for. B. a hydrostatic rotary bearing is used, which is to be operated with a time constant oil flow.

In the event that the device 10 for supplying pressure oil to several electrically controllable consumers is provided, the electronic control unit 66 also conveys the sequence in which it is switched on and off, preferably in such a way that the frequency of switching processes of the accumulator charging valve 59 is minimized.

In the embodiment represented by solid lines in the drawing, the outlet 72 of the pressure limiting valve 49 of the pressure supply unit 33 is connected directly to a drain line 73 leading to the reservoir 32, via which the pressure accumulator 52 can be emptied by manually opening a drain valve 75 which is blocked in the supply operation of the device 10 , For the "visual" control of the discharge of the pressure accumulator 52, a hydromechanical manometer 74 is provided which, independently of an activation of the electronic control unit 66, provides an indication of the accumulator pressure.

According to an expedient modification of the pressure oil supply device 10, the drain outlet 72 of the pressure limiting valve 49 is connected to the circulating flow path 58 and thus directly to the oil cooler 57 via a dashed-line drain line 76.

According to a further modification of the pressure oil supply device 10, instead of the two pressure oil filters 77 and 78, which are directly connected to the pressure outputs of the pumps 41 and 42, only one is used

Pressure oil filter 79 provided between the pressure outlet 39 of the Pressure supply device 33 and the clamping pressure setting valve 38 ge ^¬ is switched on.

Claims

claims

1.Device for supplying pressure oil to a hydraulic consumer (11; 61) operated at a defined operating pressure p _B , in the operation of which a significant leakage oil flow occurs, which is returned to the reservoir (32) of a pressure supply unit (33), which at least also provides a temporary supply of pressurized oil of a further hydraulic consumer is used, the pressure supply unit comprising a first pump (41) permanently operating in the sense of charging a pressure accumulator (52) used as a pressure source for the consumer (11; 61), and a second pump (42) which feeds a cooling circuit in an almost powerless circulating operation, in which hydraulic oil flows from the reservoir (32) via an oil cooler (54) back to the reservoir (33) of the pressure supply unit (33), and one of them

Pressure monitoring device (59, 64) controlled storage charging device (41, 42, 59), by means of which after a drop in the storage pressure below a threshold value p _S u the storage (52) can be recharged to a pressure p _s which is significantly higher than that Operating pressure p _B used in the consumer, characterized in that the first pump (41) is designed for a delivery capacity which is sufficient to cover a predetermined amount of the leak oil flow and to keep the storage pressure within a permissible variation range at a value p _s , with which there is a sufficient stability of the operating pressure p _B , which the consumer (11; 61) needs, and that the accumulator charging device comprises a pressure-controlled changeover valve (59; 59/1, 59/2) which, if the Storage pressure below the lower switching threshold psu switches the second pump (42) into a charging mode, in which this pump also charges the Druckspe ichers (52) and the pressure supply to the consumer (11), and after the memory (52) is recharged to a significantly higher switching threshold value pso, the second pump switches back to circulating operation.

Device according to claim 1, characterized in that the second pump (42) is designed for a significantly higher delivery rate than the first pump (41) provided for leakage oil compensation, preferably a delivery rate which is twice to three times the delivery rate of the first pump ( 41) corresponds.

3. Device according to claim 1 or claim 2, characterized in that the accumulator charging valve (59) is designed as a pressure-controlled valve, the lower switching threshold value p _S u, below which it mediates the switching of the second pump (42) from circulation mode to charging mode, is 5% to 20% lower than the maximum outlet pressure of the pressure supply unit (33), which is predetermined by the setting of a pressure relief valve (49), and its upper changeover threshold value p _S o, when the accumulator charging valve (59) is exceeded, the second pump ( 42) switches back to their circulation mode, is 1% to 3% lower than the maximum outlet pressure of the pressure supply unit (33).

4. Device according to one of claims 1 to 3, characterized in that at least the first pump (41) according to the

Output signal of an electronic or electromagnetic pressure sensor (64) can be controlled in such a way that the delivery rate of the first pump (41) increases compensatively as the pressure in the consumer circuit drops.

5. Device according to claim 4, characterized in that with a change in the delivery rate of the first pump (41) also the delivery rate of the second pump (42) changes in the same direction.

6. Device according to claim 5, characterized in that the two pumps (41 and 42) are designed as constant pumps, which are driven by a common electric motor (48) with control or adjustable speed.

7. Device according to one of claims 4 to 6, characterized in that an electronic or electromechanical temperature sensor (67) is provided, which generates a preferably for the temperature of the hydraulic oil in the reservoir electrical output signal, and that responsive to this output signal Electronic control unit (66) is provided, which controls an increase in the delivery capacity of at least the first pump (41) in monotonous relation with an increase in the oil temperature.

8. Device according to one of claims 1 to 7, characterized by its use for supplying pressurized oil to a hydraulic clamping cylinder (11) with which a clamping device (12) can be actuated, by means of which a workpiece can be fixed in a rotationally fixed manner on a rotatably driven work spindle (16) of a machine tool is where

a) the piston of the clamping cylinder rotatably with the working podel

(16) is connected and the pressure coupling into a

Clamping - external or internal clamping - the clamping device (12) each used pressure chamber (19 or 21) of the clamping cylinder ders (11) via a hydraulic rotary union (34), further

b) for specifying the operating pressure p _B , which the clamping cylinder (11) requires, a clamping pressure setting valve (38) is provided, which is designed as a pressure reducing valve with an adjustable outlet pressure p _B and

c) a preferably electrically controllable function control valve (22) with latched function positions (I and II) is connected between the clamping pressure specification valve (38) and the clamping cylinder (11) and the alternative clamping operating states - external and internal clamping - of the clamping cylinder (11) or the tensioning device (12) are assigned.

9. Device according to claim 8, characterized in that an electronic control unit is provided which automatically adjusts the delivery rate of at least the first pump (41) and preferably both pumps (41 and 42) as a function of the operating temperature, the spindle speed and the clamping force of the clamping cylinder , preferably in the sense of a linear superposition of the manipulated variables assigned to these parameters.

10. Device according to one of claims 1 to 9, characterized in that the oil cooler (57) has a cooling fan (71) with controllable

Cooling air delivery includes.

11. Device according to one of claims 1 to 10, characterized in that the outlet (72) of a pressure limiting valve (49) provided for specifying a maximum outlet pressure of the pressure supply unit (33) to a circulating flow path (58) is connected, which connects the changeover valve (59) with the oil cooler (27).