EP4286607A1 - Hydraulic system and working device with such a system - Google Patents

Abstract

The invention relates to a hydraulic system comprising at least two hydraulic consumers, of which at least one consumer is pressure-controlled and at least one consumer is quantity-controlled, an adjustable hydraulic pump through which the at least two consumers are supplied together, and a control arrangement. According to the invention, the hydraulic pump is electrically controlled by means of the control arrangement, the control arrangement comprising a control device and a sensor system connected to the control device for detecting at least one variable characterizing a consumer's needs, the control device being set up to use the at least one detected variable to determine the pressure required by a pressure-controlled consumer as well as a volume flow required by a quantity-controlled consumer and to regulate the hydraulic pump in such a way that the required pressure and the required volume flow are provided. The invention further relates to a working device, in particular a hydraulic excavator, with such a hydraulic system.

Description

The present invention relates to a hydraulic system according to the preamble of claim 1 and to a working device, in particular a hydraulic excavator, with such a hydraulic system.

In the case of hydraulic circuits of work machines such as hydraulic excavators, a distinction is usually made between the main hydraulics or working hydraulics (main hydraulic circuit or working hydraulic circuit), whose consumers are responsible for the functions of the equipment, and the remaining hydraulics with the auxiliary consumers (auxiliary consumer circuit). The work hydraulics are typically operated by an adjustable hydraulic pump and include all hydraulic components for performing the work functions, i.e. the operation of the equipment and attachments. The auxiliary consumer circuit with the auxiliary consumers, on the other hand, is usually operated by several differently regulated hydraulic pumps and provides other functions necessary for operating the construction machine.

Given the different functions of the auxiliary consumers, their regulation is often carried out differently. A basic distinction is made between pressure control and quantity control of the connected auxiliary consumers. Due to the different control concepts, the auxiliary consumers are often fed by differently regulated auxiliary consumer pumps. In particular, the pressure-controlled auxiliary consumers are supplied via pressure-controlled hydraulic pumps and the quantity-controlled auxiliary consumers are supplied via separate quantity-controlled auxiliary consumer pumps.

Many work machines typically require at least four hydraulic auxiliary consumers: a hydraulic engine ventilation, a hydraulic steering, a hydraulic brake and a hydraulic pilot control. According to the state of the art, the hydraulic steering and the hydraulic braking system are supplied with hydraulic oil by constant pumps or by load-sensing pumps or LS pumps. Fan drives are usually operated with pressure-controlled pumps. The pilot pressure generation for the main hydraulics is also often operated with fixed displacement pumps. Furthermore, feed pumps are required for closed hydraulic systems, for example.

However, in the event that a pressure-controlled auxiliary consumer temporarily does not require or use any hydraulic energy, the feeding pump continues to run, resulting in energetic inefficiency, since the pump control always provides a constant pressure. Combining pressure-controlled and volume-controlled adjustable hydraulic pumps into a common hydraulic pump represents a major challenge due to the different control principles and the resulting high susceptibility to vibration and design complexity.

Newer systems, such as those in US 6,314,729 B1 and US 6,848,255 B2 are disclosed are operated by an LS pump. However, such systems have the disadvantage that the LS control of the various consumers is extremely susceptible to vibration. In order to remedy this disadvantage, the describes DE 10 2016 000 186 A1 a system with combined LS and pressure control for a common variable displacement pump. However, this regulation also has the disadvantage that it is a certain susceptibility to vibration.

The present invention is therefore based on the object of overcoming the disadvantages of the prior art and finding a suitable system that enables a stable common supply of quantity-controlled and pressure-controlled consumers.

This object is achieved according to the invention by a hydraulic system with the features of claim 1. Advantageous embodiments of the invention result from the subclaims and the following description.

Accordingly, a hydraulic system is proposed with at least two hydraulic consumers supplied together via an adjustable hydraulic pump and a control arrangement for controlling the hydraulic pump. Of the at least two consumers, at least one consumer is pressure-controlled and at least one consumer is quantity-controlled. The consumers supplied via the common hydraulic pump can be auxiliary consumers of a work machine, such as fans, steering, brakes and/or pilot control. The hydraulic system can be an auxiliary consumer circuit of a work machine or part of one.

According to the invention, an electrical control of the hydraulic pump is provided, ie the hydraulic pump is electrically controlled by means of the control arrangement. The control arrangement includes a control device and a sensor system connected to the control device for detecting at least one variable that characterizes the need of at least one consumer. The need of the respective consumer preferably relates to a pressure provided by the hydraulic pump or a delivery volume provided. A recorded variable can represent a requirement itself, for example a pressure recorded via a pressure sensor. Alternatively or additionally, the demand of a consumer can be derived from a recorded variable or determined by the control device.

According to the invention, the control device is set up to use the at least one variable detected by the sensor system to determine a pressure required by at least one pressure-controlled consumer and a volume flow required by at least one quantity-controlled consumer and to regulate the hydraulic pump in such a way that the required pressure and the required volume flow be made available to the relevant consumers.

It can be provided that the required pressure for one or more pressure-controlled consumers is not determined based on sensor signals, but is stored as a fixed and/or definable value in a memory to which the control device has access. The required volume flow is preferably derived from the signals from one or more sensors. Of course, it is alternatively or additionally conceivable to determine the required pressure of one or more consumers using pressure sensors.

The hydraulic system according to the invention makes it possible to supply several differently regulated consumers with one and the same hydraulic pump without having to buy this through a complicated and vibration-prone control arrangement. The joint supply of several consumers through a common electrically controlled displacement unit also results in significant energy savings.

Another advantage of the electrical control according to the invention is that the hydraulic pump can be completely torque-free when starting a working device that includes the hydraulic system. This reduces the torque when starting the implement.

In a possible embodiment it is provided that the hydraulic system comprises a second valve unit, which is connected between the hydraulic pump and at least one quantity-controlled consumer. The second valve unit can be part of the consumer in a broader sense.

It is preferably provided that the second valve unit is not electrically controlled by the control unit. The second valve unit can be controlled hydraulically.

In a further possible embodiment it is provided that the sensor system comprises a pressure sensor which detects a pressure in the second valve unit, in particular in a control line of the second valve unit. The measured pressure is made available to the control unit and is preferably used by it to determine a volume flow requirement of the quantity-controlled consumer supplied via the second valve unit. In addition to the measured pressure value, other variables recorded by additional sensors can be used.

In a further possible embodiment, a first valve unit that hydraulically connects the at least two consumers to the hydraulic pump is provided. The first valve unit is preferably not electrically controlled by the control unit. The first valve unit is therefore preferably not activated electrically, but rather hydraulically.

The first valve unit can be designed to direct hydraulic oil from the hydraulic pump to the second valve unit in a first switching position, and to block the hydraulic flow to the second valve unit in a second switching position. Alternatively, the first valve unit can be designed to allow a hydraulic flow to the second valve unit in every switching position, and to block the hydraulic oil flow in a specific switching position at a further output. This is particularly useful if the consumer connected to the hydraulic pump via the second valve unit is a steering device or part thereof, since the steering device must always and primarily be supplied with hydraulic oil.

In a further possible embodiment it is provided that the second valve unit is located between the first valve unit and at least one quantity-controlled valve unit consumer is switched. Preferably, the first valve unit is connected to the second valve unit via a hydraulic control line. In this case, the previously described pressure sensor of the sensor system detects in particular a pressure in the control line between the first and second valve unit.

In a further possible embodiment it is provided that at least one hydraulic steering device or a part thereof (e.g. one or more steering cylinders for deflecting one or more wheels of an implement) is provided as a quantity-controlled consumer, which is connected in particular via the described second valve unit to the first valve unit connected is. The second valve unit can also be part of the steering device and represent or comprise a steering valve block.

The sensor system preferably comprises a speed sensor coupled to the steering device, which is used to detect a steering speed. The speed sensor can be provided on a steering linkage. The measured speed value is made available to the control unit and is preferably used by it to determine a volume flow requirement of the steering device. In addition to the measured speed value, other variables recorded by additional sensors can be used, for example a pressure value.

In a further possible embodiment it is provided that the first valve unit is set up to supply at least one consumer with hydraulic oil with priority over at least one other consumer. Preferably, a quantity-controlled consumer is given priority over a pressure-controlled consumer. The consumer supplied with priority can be a steering device or part of it.

In a further possible embodiment it is provided that the first valve unit comprises a switchable priority valve, which preferably exclusively has one or more quantity-controlled consumers in a first switching position (for example a steering device) and in a second switching position supplies the at least one quantity-controlled consumer and one or more pressure-controlled consumers in parallel. The priority valve can be designed as a continuously switchable directional control valve.

In a further possible embodiment it is provided that the control arrangement comprises an adjusting means for adjusting a pressure and/or a pivot angle of the hydraulic pump, which is electrically connected to the control unit. Based on the control or regulation commands from the control unit, the actuator adjusts the hydraulic pump in such a way that the desired pressure or the desired volume flow is achieved at the respective consumers.

In a further possible embodiment, it is provided that at least one pressure-controlled consumer is connected to the hydraulic pump, in particular to the previously described first valve unit, via a third valve unit, wherein the third valve unit can preferably be electrically controlled by the control unit via an electrical control line. The term “controllable” includes the control as part of a regulation of the third valve unit. The third valve unit can include or represent a pressure reducing valve, which reduces the pressure applied to the assigned consumer to a defined value if the pressure level at the inlet of the pressure reducing valve is too high. The limit value from which the pressure reducing valve switches is preferably specified by the control device, which can be connected to an electrical control input of the pressure reducing valve.

In a further possible embodiment it is provided that at least one pressure-controlled consumer can be supplied with hydraulic pressure via a hydraulic accumulator, the hydraulic accumulator preferably being rechargeable via the hydraulic pump. The hydraulic accumulator can include one or more individual accumulators. The hydraulic accumulator can be connected to the assigned consumer via a switching valve.

In a further possible embodiment it is provided that the sensor system comprises a pressure sensor which detects a pressure prevailing in the hydraulic accumulator and thereby in particular permanently monitors the fill level of the hydraulic accumulator. The control arrangement is preferably set up to regulate the hydraulic pump depending on the signals from the pressure sensor in such a way that the hydraulic accumulator is filled, for example when the level falls below a certain minimum level. For this purpose, the signals from the pressure sensor are made available to the control unit.

In a further possible embodiment it is provided that a consumer connected to the hydraulic accumulator is a hydraulic braking device. The pressure in the brake system can be monitored via the pressure sensor mentioned.

In a further possible embodiment, a hydraulic motor for a fan unit and/or a hydraulic pilot control is provided as a pressure-controlled consumer. A pressure reducing valve and/or a pressure reducing valve can be connected upstream of the fan motor or the pilot control.

It can be provided that several pressure-controlled consumers are connected in parallel to the first valve unit, in particular in parallel to one or more quantity-controlled consumers. Some or all of the pressure-controlled consumers can be connected to the first valve unit via a third valve unit. Alternatively, one or more consumers can be connected directly to the first valve unit.

In a further possible embodiment it is provided that, in addition to the electrically controlled hydraulic pump, there is no further pump to supply the consumers. This results in a particularly simple and energy-efficient hydraulic system for supplying and regulating the various consumers.

The present invention further relates to a working device with a hydraulic system according to the invention. This results in the same advantages and properties as previously described for the hydraulic system according to the invention, which is why a repeat description is omitted. The working device can in particular be a hydraulic excavator, although the working device according to the invention is not limited to this. The hydraulic system according to the invention can, for example, be part of a wheel loader, dumper or telehandler. The hydraulic system according to the invention is preferably part of an auxiliary consumer circuit of the implement.

Figur 1:

einen schematischen Schaltplan des erfindungsgemäßen Hydraulik-systems gemäß einem ersten Ausführungsbeispiel;

Figur 2:

einen schematischen Schaltplan des erfindungsgemäßen Hydraulik-systems gemäß einem zweiten Ausführungsbeispiel;

Figur 3:

eine detailliertere Darstellung des Hydrauliksystems gemäß Figur 2; und

Figur 4:

einen schematischen Schaltplan des erfindungsgemäßen Hydraulik-systems gemäß einem dritten Ausführungsbeispiel.

Further features, details and advantages of the invention result from the exemplary embodiments explained below with reference to the figures. Show it:

Figure 1:

a schematic circuit diagram of the hydraulic system according to the invention according to a first exemplary embodiment;

Figure 2:

a schematic circuit diagram of the hydraulic system according to the invention according to a second exemplary embodiment;

Figure 3:

a more detailed representation of the hydraulic system Figure 2 ; and

Figure 4:

a schematic circuit diagram of the hydraulic system according to the invention according to a third exemplary embodiment.

In the Figure 1 A first exemplary embodiment of the hydraulic system according to the invention is shown as a schematic circuit diagram. The hydraulic system can be part of an auxiliary consumer circuit of a work machine such as a hydraulic excavator, via which several auxiliary consumers are supplied with hydraulic oil.

In the hydraulic system according to the invention, several pressure-controlled and quantity-controlled hydraulic consumers are provided, which are supplied via a single adjustable hydraulic pump 10. The hydraulic pump 10 can be, for example, an axial piston pump.

The output of the hydraulic pump 10 is connected to an input of a first valve block 30 (= first valve unit), which primarily supplies a second valve block 120 (= second valve unit) with hydraulic oil. The second valve block 120 is connected to a second output of the first valve block 30 via a supply line. In addition, the two valve blocks 30, 120 are connected to one another via a hydraulic control line, the pressure of which is detected by a first pressure sensor 80. The control line can be an LS signaling line.

In the exemplary embodiment shown here, the second valve block 120 is part of a hydraulic steering device, which also includes one or more hydraulic steering cylinders 110. The steering cylinder or cylinders 110 ensure a deflection of steered wheels of the implement (not shown) when one of the pressure chambers is pressurized accordingly.

The steering device further comprises a steering wheel 100 with a steering linkage, which is coupled to the second valve block 120 in such a way that a specific deflection of the steering wheel 100 leads to a specific adjustment of the steering cylinder(s) 110 and thus to a specific deflection of the wheels. A speed sensor 90 is connected to the steering linkage and detects an angle and/or an angular velocity and thus the steering speed.

The steering cylinder or cylinders 110 represent the hydraulic consumer in the narrower sense, with the entire steering device being referred to below as a hydraulic consumer for the sake of simplicity. The steering device is a quantity-controlled consumer which requires a certain volume flow from the hydraulic pump 10.

In addition to the steering device as a quantity-controlled consumer, a pressure-controlled consumer 60 is provided, which in this exemplary embodiment is a hydraulic fan motor 60 for driving a ventilation system of the implement. The fan motor 60 is connected to a first output of the first valve block 30 via a pressure reducing valve 50 (= third valve unit).

The hydraulic pump 10 can be adjusted via an adjusting means 20 in the form of a pump controller in order to deliver a specific volume flow and pressure. The adjusting means 20 can be a pressure regulator and/or swivel angle regulator. The hydraulic pump 10 is controlled via the pump controller 20 in such a way that at the same time the fan motor 60 can be operated with the required pressure and the steering device can be provided with the required volume flow.

In contrast to systems known from the prior art, the hydraulic pump 10 is not controlled by an LS control or a combination of several LS, pressure and possibly power regulators, but rather via an electrical control arrangement. An electro-hydraulic displacement unit is therefore used to supply all consumers of the hydraulic system.

The control arrangement includes an electrical control unit 40 (ECU = electronic control unit), which is connected to the various sensors 80, 90 and receives and processes their signals. From the pressure measured by the first pressure sensor 80 in the control line between the valve blocks 30, 120 and the signals from the speed sensor 90, the control device 40 calculates a volume flow required by the steering device and generates a control signal for the pump controller 20, to which the control device 40 is electrically connected is. The control device 40 therefore makes a corresponding target specification to the controller 20, whereupon it regulates the hydraulic pump 20 in such a way that it delivers the requested volume flow.

The valve block 30 can be designed as a so-called priority valve, which connects the pump output in a first switching position only to the steering device and in a second switching position connects in parallel with the steering device and with the fan motor 60. The steering device is preferably supplied, since its function is essential for the operation of the implement.

The fan motor 60 must be operated at a specific pressure (which corresponds to a specific speed requirement for the fan), i.e. it is pressure regulated. In order to provide the required pressure, a third valve unit in the form of an electrically controllable pressure reducing valve 50 is connected between the fan motor 60 and the first output of the first valve block 30, the control input of which is electrically connected to the control unit 40. The control unit 40 controls the limit pressure of the pressure reducing valve 50, for example based on a specification for operating the ventilation system or a speed requirement. As long as the pressure at the first output of the first valve block 30 is greater than the limit pressure of the pressure reducing valve 50 set by the control unit 40, the same pressure is always present at the fan motor 60. The pressure request is in turn made available to the pump controller 20 as a setpoint specification by the control unit 40. The hydraulic motor 10 is in particular controlled in such a way that the pressure provided is greater than or equal to the limit pressure of the pressure reducing valve 50.

The pressure-controlled consumer can generally be a hydraulic motor (such as the fan motor 60 of the exemplary embodiment shown here), a valve block or any other pressure-controlled consumer. Several pressure-controlled consumers can also be connected to the first valve block 30 in parallel to one another. Such an exemplary embodiment is shown in FIG. Components with already in the Figure 1 Reference numerals shown are identical to the embodiment Figure 1 and will not be described again here.

A hydraulic pilot control 140 is provided as an additional pressure-controlled consumer, which is connected directly to the first output of the first valve block 30. A hydraulic pressure reducing valve 130 can be connected upstream of the pilot control 140. The pilot control 140 can include or represent a control oil unit which provides a specific control pressure (e.g. 30 bar) for other components of the hydraulic system (e.g. for a main consumer circuit).

Furthermore, a hydraulic braking device 170 is provided as a further pressure-controlled consumer, which is connected directly to the first output of the first valve block 30 in parallel to the other pressure-controlled consumers 60, 140. The braking device 170 may include a brake valve (for example a dual-circuit brake valve) with a brake pedal.

The braking device is supplied with pressure via a hydraulic accumulator 150. The pressure in the memory 150 is continuously monitored for the current level by a second pressure sensor 160 electrically connected to the control device 40 and the signals are made available to the control device 40. If the pressure in the hydraulic accumulator 150 falls below a defined limit value (this can be stored in the control device or a memory connected to it), the control device 40 sends the pump controller 20 a corresponding signal to swing out the hydraulic pump 10 in order to load the hydraulic accumulator 150. The charging process continues until the hydraulic accumulator 150 is filled.

If the pressure requirement for the hydraulic accumulator 150 is higher than the pressure requirement for the fan motor 60, the pressure is reduced accordingly by the pressure reducing valve 50.

If the pressure on the steering device is too high (for example due to a charging process of the hydraulic accumulator 150 and a corresponding pressure generation by the hydraulic pump 10), the second valve block 120 preferably regulates the excess pressure independently (similar to a pressure compensator).

This makes it possible for a single pump controller 20 and a single hydraulic pump 10 to provide both a required volume flow for the steering device and the required and usually different pressures for the hydraulic accumulator 150, pilot control 140, fan motor 60 and steering device.

Due to the purely electrical design of the pump controller 20, the hydraulic pump 10 can be completely torque-free during the starting process. This reduces the torque when starting the machine, making the starting process much easier.

The control arrangement supplies the various auxiliary consumers with the required amount of oil as required by a single adjustable hydraulic pump.

The Figure 3 shows the exemplary embodiment of the hydraulic system Figure 2 in a more detailed view. Here, among other things, the dual-circuit brake valve 170 can be seen, which connects two individual hydraulic accumulators 150 with the hydraulic brakes. A check valve is connected between the brake valve 170 and the hydraulic accumulator 150 on the one hand and the first valve block 30 on the other hand and blocks hydraulic backflow from the accumulator 150 to the first valve block 30.

Furthermore, the priority valve 30 can be seen with its two switching positions (first, in the Figure 3 lower switching position: sole power supply for the steering device; second, in the Figure 3 upper switching position: parallel supply of the steering device and the other pressure-controlled consumers).

The structure of the steering valve or the second valve block 120 can also be seen. The priority valve 30 is not controlled via the control device 40, but hydraulically via the control line connected to the second valve block 120. In the Figure 4 A third exemplary embodiment of the hydraulic system according to the invention is shown as a schematic circuit diagram. The only difference compared to the exemplary embodiment Figure 1 is that no first valve block 30 (first valve unit) is provided. Instead, the pressure reducing valve 50 and the second valve block 120 (second valve unit) are connected directly to the hydraulic pump 10. The pressure sensor 80 detects the pressure in a hydraulic line of the second valve block 120, which can be, for example, a hydraulic control line of the second valve block 120. In the exemplary embodiment of Figure 4 There is therefore no prioritization of the hydraulic flow to the second valve block 120, whereas the previously described electrical control according to the invention continues to be carried out by the control unit 40.

List of reference symbols:

10

Hydraulic system

20

Actuator (pump controller)

30

First valve unit

40

Control unit

50

Third valve unit

60

Pressure-controlled consumer (fan motor)

80

Pressure sensor

90

Speed sensor

100

steering wheel

110

Steering cylinder

120

Second valve unit

130

Pressure reducing valve

140

Pilot control

150

Hydraulic accumulator

160

Pressure sensor

170

Braking device

Claims (15)

Hydraulic system comprising at least two hydraulic consumers, of which at least one consumer is pressure-controlled and at least one consumer is quantity-controlled, an adjustable hydraulic pump (10), via which the at least two consumers are supplied together, and a control arrangement,
characterized,
in that the hydraulic pump (10) is electrically controlled by means of the control arrangement, the control arrangement comprising a control device (40) and a sensor system connected to the control device (40) for detecting at least one variable characterizing a consumer's needs, the control device (40) being set up is to use the at least one recorded variable to determine a pressure required by a pressure-controlled consumer and a volume flow required by a quantity-controlled consumer and to regulate the hydraulic pump (10) in such a way that the required pressure and the required volume flow are provided. Hydraulic system according to claim 1, further comprising a second valve unit (120) which is connected between the hydraulic pump (10) and at least one quantity-controlled Consumer is switched and is preferably not electrically controlled by the control unit (40). Hydraulic system according to the preceding claim, wherein the sensor system comprises a pressure sensor (80) which detects a pressure in the second valve unit (120), in particular in a control line of the second valve unit (120). Hydraulic system according to one of the preceding claims, further comprising a first valve unit (30), which connects the at least two consumers to the hydraulic pump (10) and is preferably not electrically controlled by the control unit (40). Hydraulic system according to claim 4 and one of claims 2 to 3, wherein the second valve unit (120) is connected between the first valve unit (30) and at least one quantity-controlled consumer, the first valve unit (30) preferably being connected to the second valve unit via a hydraulic control line (120) is connected and the sensor system includes in particular a pressure sensor (80) which detects a pressure in the control line between the first and second valve units (30, 120). Hydraulic system according to one of the two preceding claims, wherein the first valve unit (30) is set up to supply at least one, in particular quantity-controlled, consumer (110) with hydraulic oil with priority over at least one other, in particular pressure-controlled, consumer (60, 140, 170). Hydraulic system according to the preceding claim, wherein the first valve unit (30) comprises a switchable priority valve, which preferably exclusively has one or more quantity-controlled consumers (110) in a first switching position and the at least one quantity-controlled consumer (110) and one or more in parallel in a second switching position several pressure-controlled consumers (60, 140, 170) are supplied. Hydraulic system according to one of the preceding claims, wherein at least one quantity-controlled consumer (110) is part of a hydraulic steering device (100, 110, 120), the sensor system preferably using a speed sensor (90) coupled to the steering device (100, 110, 120) for detection a steering speed includes. Hydraulic system according to one of the preceding claims, wherein the control arrangement comprises an adjusting means (20) for adjusting a pressure and/or a pivot angle of the hydraulic pump (10), which is electrically connected to the control unit (40). Hydraulic system according to one of the preceding claims, wherein at least one pressure-controlled consumer (60) is connected to the hydraulic pump (10) via a third valve unit (50), the third valve unit (50) preferably electrically via an electrical control line through the control unit (40). can be controlled. Hydraulic system according to one of the preceding claims, wherein at least one pressure-controlled consumer (170) can be supplied via a hydraulic accumulator (150), the hydraulic accumulator (150) preferably being rechargeable via the hydraulic pump (10), with a consumer connected to the hydraulic accumulator (150). in particular a hydraulic braking device (170). Hydraulic system according to the preceding claim, wherein the sensor system comprises a pressure sensor (160) which detects a pressure prevailing in the hydraulic accumulator (150), the control arrangement preferably being set up to control the hydraulic pump (10) in such a way as a function of a signal from the pressure sensor (160). ensure that the hydraulic accumulator (150) is filled. Hydraulic system according to one of the preceding claims, wherein a hydraulic motor (60) for a fan unit and/or a hydraulic pilot control (140) is provided as the pressure-controlled consumer, which preferably a pressure reducing valve (130) and/or a pressure reducing valve (50) is connected upstream. Hydraulic system according to one of the preceding claims, wherein in addition to the hydraulic pump (10), no further pump is provided to supply the consumers. Working device, in particular a hydraulic excavator, with a hydraulic system according to one of the preceding claims, wherein the hydraulic system is preferably part of an auxiliary consumer circuit of the working device.

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