EP2504586A2

EP2504586A2 - Hydraulic drive

Info

Publication number: EP2504586A2
Application number: EP10788237A
Authority: EP
Inventors: Bernard De Muynck
Original assignee: Haco NV
Current assignee: Haco NV
Priority date: 2009-11-23
Filing date: 2010-11-22
Publication date: 2012-10-03
Also published as: WO2011060955A2; DE102009054158A1; WO2011060955A3

Abstract

The invention relates to a hydraulic drive (A) for driving at least one hydraulic actuator, comprising at least one hydraulic pump (2) that can be driven by an electric motor (M) and at least one hydraulic line (L) conducting a hydraulic fluid, via which line the hydraulic pump (2) can be connected to the hydraulic actuator. In order to provide an energy-efficient hydraulic drive (A) that can be operated cost-effecitvely, according to the invention said drive comprises at least one unit (7) for detecting the actual pressure in the hydraulic line (L) and an electronic control unit (10) connected to said unit, the control unit being connected to the electric motor (M) and designed such that it automatically shuts off the electric motor (M) when the detected actual pressure is equal to or greater than a predeterminable target pressure and automatically turns it on when the actual pressure is smaller than the target pressure.

Description

The invention relates to a hydraulic drive for driving at least one hydraulic actuator, comprising at least one hydraulic pump drivable by an electric motor and at least one hydraulic fluid conducting hydraulic line, via which the hydraulic pump can be connected to the hydraulic actuator. The invention further relates to a hydraulic system with at least one hydraulic actuator and a method for operating a hydraulic drive, which is equipped with at least one electric motor for driving a hydraulic pump and with which the properties of a hydraulic fluid can be varied so that it matches the properties of at least one hydraulic actuator to be supplied with the hydraulic actuator can be adapted.

Hydraulic drives are known in various designs and are used to drive hydraulic actuators, such as hydraulic cylinders or the like. For this purpose, a hydraulic drive via at least one hydraulic line with the hydraulic actuator can be connected in order to be able to drive this in the desired manner. For this purpose, the hydraulic line conducts a hydraulic fluid, for example a hydraulic oil or the like, the flow of which can be controlled in particular via hydraulic valves. The latter are suitably controlled to drive the hydraulic drive, i. opened and closed.

CONFIRMATION COPY In conventional hydraulic drives, it is disadvantageous that the electric motor remains continuously switched on even in idling phases in which no energy is required for driving the hydraulic actuator. As a result, energy is unnecessarily consumed in idle phases, which increases the costs associated with the operation of a conventional hydraulic drive costs. Furthermore, at least the electric motor and the associated hydraulic pump of a conventional hydraulic drive suffer relatively high wear, since these components are also in the idling phases in operation. This in turn is associated with increased maintenance costs and reduced service life of such a hydraulic drive.

Based on this prior art, it is the object of the invention to provide a hydraulic drive which is energy-efficient and inexpensive to operate.

This object is achieved by a hydraulic drive of the type mentioned in that it comprises at least one means for detecting the actual pressure in the hydraulic line and an associated electronic control device which is connected to the electric motor and is arranged such that it the electric motor automatically shuts off when the detected actual pressure is equal to or greater than a predetermined target pressure, and automatically turns on when the actual pressure is less than the target pressure.

According to the invention, the electric motor is only switched on when it is determined via the electronic control device that the actual pressure present in the hydraulic line falls below a predefinable setpoint pressure, since in such a state the required energy for suitably driving the hydraulic actuator is not present. However, if a sufficient pressure in the hydraulic line is present, that is, the actual pressure is greater than or equal to the predetermined target pressure, the electric motor is automatically switched off so as not to consume energy even in idle phases in which the hydraulic actuator is not used , This shutdown of the electric motor in idle phases of this and also over the electric motor drivable hydraulic pump are also against wear protected, so that a hydraulic drive according to the invention can be operated with lower maintenance costs and longer service lives. The hydraulic drive according to the invention is thus energy efficient and inexpensive to use. The electric motor may in this case be servo-controlled, for example. The operation of conventional hydraulic drives usually involves idling phases, which account for about 90% of the total operating time. The hydraulic drive according to the invention thus enables a significant reduction in energy costs by automatically switching off the electric motor in the idling phases. This shutdown of the electric motor is also associated with a significant reduction in heat generation, which occurs during operation of the electric motor and thus driven hydraulic pump and can adversely affect the operation of the hydraulic drive. Advantageously, the heat still generated by the electric motor or the hydraulic pump is dissipated and used for other purposes.

The hydraulic drive according to the invention can be used for example in bridge constructions, cranes, ships, drilling rigs or the like, but in particular in any type of hydraulic presses. In the context of the invention it is also possible to drive a plurality of hydraulic actuators with a single hydraulic drive. For this purpose, the hydraulic drive can have one or more hydraulic pumps. In this regard, any number of configurations of the hydraulic drive are considered as lying within the scope of the invention.

Preferably, the duration of idle phases and operating phases is detected by the electronic control or regulating device. Parameters can be specified which prevent the electric motor from being switched off automatically in any idling phase. Instead, a shutdown of the electric motor can then take place when an idle phase of a certain duration, that is, according to the predetermined parameters, is present.

According to an advantageous embodiment of the invention, the hydraulic drive has at least one connected to the electronic control device Means for detecting the actual temperature in the hydraulic line, wherein the control device for automatically controlling the temperature in the hydraulic line based on the detected actual temperature is set in relation to a predetermined target temperature. In this way it can be ensured that the respectively used hydraulic fluid is in a state which enables optimum operation of the hydraulic drive and which is characterized in particular by the actual temperature of the hydraulic fluid. By means of the electronic control device is preferably a comparison of the detected actual temperature in the hydraulic line with the predetermined target temperature. If the detected actual temperature deviates from the predefinable setpoint temperature by a certain amount, then the hydraulic fluid can be heated or cooled to the respectively optimum operating temperature as a function of the result of the comparison. This can be done with a suitable heating and / or cooling device. Keeping the hydraulic fluid at its optimum operating temperature is also important for the energy efficiency of a hydraulic drive, especially since the actual temperature is directly related to the viscosity characteristics of the hydraulic fluid.

According to a further advantageous embodiment of the invention, the hydraulic drive at least one device connected to the electronic control device for detecting the actual flow in the hydraulic line, wherein the control device for automatically controlling the flow in the hydraulic line based on the detected actual flow in relation is set up for a predetermined target flow. The regulation of the flow of hydraulic fluid in the hydraulic line serves to provide an optimal and energy-efficient operation of the hydraulic drive. The electronic control device preferably compares the respectively detected actual flow with the predefinable desired flow and regulates the actual flow to an optimum value as a function of the result of this comparison. Furthermore, it can be determined by the detection of the actual flow, whether the hydraulic actuator is currently supplied with energy or must be or whether no energy is needed, so that the electric motor can be turned off. A further advantageous embodiment of the invention provides that the hydraulic drive has at least one hydraulic fluid reservoir, which can be connected to the hydraulic line via a hydraulic fluid supply line. Preferably, the hydraulic fluid supply line via the hydraulic pump with the hydraulic line is connectable. By providing a hydraulic fluid reservoir, it is possible, for example, to compensate for an adverse leakage of hydraulic fluid by supplying hydraulic fluid from the hydraulic fluid reservoir to the hydraulic line. On the other hand, an excess of hydraulic fluid, which can be detected, for example, by an excessively high actual pressure in the hydraulic line, be discharged from the hydraulic line to the hydraulic fluid reservoir in order to obtain optimum operating parameters for the hydraulic drive. The supply and removal of hydraulic fluid to or from the hydraulic line can for example be done automatically by means of the electronic control device, which controls the hydraulic valves provided for this purpose in a suitable manner.

In principle, according to the invention, it is always possible to recover hydraulic and / or electrical energy and, for example, to use it profitably in presses in which large loads have to be moved. Excess pressure in the hydraulic system can be used to generate electrical energy.

It is further proposed that the hydraulic fluid reservoir is provided with a heating and / or cooling unit. This serves to heat supply hydraulic fluid to a temperature which ensures optimum operation of the hydraulic drive, or to cool discharged hydraulic fluid. The heat extracted from the hydraulic fluid during cooling can be dissipated and used for other purposes. A heating of the hydraulic fluid is particularly advantageous when using the hydraulic drive under very low ambient temperatures. On the other hand, a cooling of the hydraulic fluid is advantageous when the hydraulic drive is used in very hot environments.

It is also advantageous if the hydraulic fluid reservoir is equipped with a device for filtering the hydraulic fluid. This can dissipated Hydraulic fluid, which may have been contaminated during its use, to be filtered before it is supplied to the hydraulic fluid reservoir. The filtering may alternatively or in combination therewith also take place before the hydraulic fluid is fed into the hydraulic line and after it has been removed from the hydraulic fluid reservoir.

According to a further advantageous embodiment of the invention, the hydraulic drive has at least one device which can be connected to the hydraulic line for storing the hydraulic fluid under a prescribable pressure. This device, also referred to as an accumulator, can be used to feed hydraulic fluid under optimum pressure into the hydraulic line when the hydraulic pump is not yet turned on or in its start-up phase, but there is already a demand for energy due to the activity of the hydraulic actuator , Furthermore, this device can be used to dampen peak loads occurring in the pressure curve. In such situations, additional pressurized hydraulic fluid is needed which can be provided by this device. Furthermore, the device can be filled again with hydraulic fluid, which preferably takes place via a suitable pressure generation by means of the hydraulic pump. Such a rechargeable battery is a device for the efficient storage of hydraulic energy, which can be called up at any time.

It is further proposed that the hydraulic drive has at least one pressure relief valve arranged on the hydraulic line. This safety device serves to discharge hydraulic fluid from the hydraulic line when the actual pressure in the system is such that damage to components of the hydraulic drive is to be feared. For this purpose, the overpressure valve can be controlled automatically or by means of the electronic control device, which actuates the overpressure valve on the basis of detected actual parameters and a comparison with corresponding desired parameters. The hydraulic fluid discharged via the pressure relief valve is preferably supplied to the hydraulic fluid reservoir. A further advantageous embodiment of the invention provides that the hydraulic pump is combined with at least one device connected to the electronic control device for detecting the flow of the hydraulic fluid. Also, the actual parameters detected with this device can be utilized to provide optimal operation of the hydraulic drive.

Advantageously, the electronic control device comprises means for inputting desired hydraulic fluid values and / or means for displaying detected actual hydraulic fluid values. These means provide an interface to the operator of the hydraulic drive and at the same time allow, inter alia, a manual adjustment of the hydraulic drive to a variety of uses, while the given operating parameters can be monitored. For example, desired pressure values, desired temperature values, desired flow values or the like can be input via the means for inputting desired hydraulic fluid values. In addition, parameters can be entered, which determine from which duration of an idle phase an automatic shutdown of the electric motor makes sense. The means for displaying actual values of hydraulic fluid can have, for example, a monitor on which, for example, the actual pressure, the actual temperature, the actual flow, the energy consumption, statistical information, information messages, error messages, maintenance warnings or the like are displayed can.

It is also proposed that the hydraulic drive has two or more hydraulic pumps. As a result, the variability of the possible applications of the hydraulic drive is significantly increased. Preferably, the hydraulic pumps differ in their dimensions and / or performance.

The invention further proposes a hydraulic system of the type mentioned, which has at least one hydraulic drive according to one of the above-described embodiments or any combination thereof for achieving the above object. It is further proposed a method of the type mentioned, which solves the above issue in that at least the actual pressure of the hydraulic fluid is detected, the detected actual pressure is compared with a predetermined target pressure, and the electric motor is turned on automatically if the actual pressure is less than the target pressure value and automatically shuts off when the actual pressure is equal to or greater than the target pressure.

With invention thus a very variable usable, energy-efficient and cost-operable hydraulic drive is proposed. Within the scope of the invention, it should be understood that, for example, also a plurality of desired values of the same type can be used. This may be desirable, for example, when the setpoint pressure, from which the electric motor is to be automatically switched off, is to differ from the setpoint pressure, below which the electric motor is to be switched on again automatically. The same can apply to the other control parameters mentioned, such as setpoint temperature, setpoint flow and the like.

Further advantages and features of the invention are explained below with reference to the embodiment shown in the accompanying figure. It shows

Figure 1: a schematic representation of a

Embodiment for the hydraulic drive according to the invention.

FIG. 1 schematically shows an exemplary embodiment of the hydraulic drive A according to the invention. The latter can be connected via a hydraulic line L to a hydraulic actuator (not shown). The hydraulic drive A has a hydraulic pump 2, which can be driven by an electric motor M. Downstream of the hydraulic pump 2 is a device 7 for detecting the actual pressure in the hydraulic line L. This device 7 is connected to an electronic control device 10, which in turn is connected to the electric motor M and arranged such that it automatically shuts off the electric motor M when the detected actual pressure is equal to or greater than a predetermined target pressure, and automatically turns on when the actual pressure is smaller than the target pressure. This control of the hydraulic drive A is associated with the above-described advantages of energy efficiency and cost-effectiveness.

The hydraulic drive A further has a device 6 connected to the electronic control device 10 for detecting the actual temperature in the hydraulic line L, the control device 10 for automatically regulating the temperature in the hydraulic line L on the basis of the detected actual temperature in relation to a predetermined target temperature is set up.

The hydraulic drive A also has a device 8 connected to the electronic control device 10 for detecting the actual flow in the hydraulic line L. The control device 10 is designed to automatically regulate the flow in the hydraulic line L on the basis of the detected actual flow in relation to a predefinable target flow. The outlet of the hydraulic line L is at 12.

The hydraulic drive A also has a hydraulic fluid reservoir 1 which can be connected to the hydraulic line L via a hydraulic fluid supply line 11 and the hydraulic pump 2. If necessary, it is possible to discharge hydraulic fluid via the hydraulic pump 2 to the hydraulic fluid reservoir 1 or to supply it from this. The hydraulic fluid reservoir 1 has a heating and / or cooling unit with which the hydraulic fluid to be supplied can be heated to a desired temperature or hydraulic fluid discharged can be cooled. Furthermore, the hydraulic fluid reservoir 1 has a device (not shown in greater detail) for filtering the hydraulic fluid.

The hydraulic drive A further comprises a connectable to the hydraulic line L means 5 for storing of under a predetermined pressure standing hydraulic fluid (accumulator). This can supply (possibly pressurized) hydraulic fluid as needed, for example, to compensate for peak loads in the pressure curve and to be able to dampen. Arranged on the hydraulic line L is a pressure relief valve 9, which discharges hydraulic fluid from the hydraulic line L into the hydraulic fluid reservoir 1 when there is a harmful overpressure present in the hydraulic line L.

The hydraulic pump 2 is combined with at least one device (not shown) connected to the electronic control device 10 for detecting the flow of the hydraulic fluid.

In the hydraulic line L is preferably between the pump 2 and the accumulator 5, an electrically operated pressure relief valve 3 is switched on and, downstream of the accumulator 5, a 1-way valve 4. The electronic control device 10 has means for inputting hydraulic fluid target values and means for displaying detected hydraulic fluid actual values. By way of the means for inputting desired hydraulic fluid values, it is possible, for example, to specify a desired pressure, a desired temperature and a desired flow. The detected hydraulic fluid actual values can be displayed to the operating personnel of the hydraulic drive A, for example, on a monitor and thus monitored in a simple manner.

The embodiment described with reference to the figure is illustrative and is not limiting.

- Claims -

Claims

claims

1 . Hydraulic drive (A) for driving at least one hydraulic actuator, comprising at least one of an electric motor (M) drivable hydraulic pump (2) and at least one hydraulic fluid conducting hydraulic line (L) via which the hydraulic pump (2) connectable to the hydraulic actuator characterized by at least one means (7) for detecting the actual pressure in the hydraulic line (L) and an associated electronic control device (10) connected to the electric motor (M) and adapted to connect the electric motor (M ) automatically turns off when the detected actual pressure is equal to or greater than a predetermined target pressure, and automatically turns on when the actual pressure is smaller than the target pressure.

2. Hydraulic drive (A) according to claim 1, characterized by at least one with the electronic control device (10) connected to means (6) for detecting the actual temperature in the hydraulic line (L), wherein the control device (10) for automatically controlling the Temperature in the hydraulic line (L) on the basis of the detected actual temperature is set in relation to a predetermined target temperature.

3. Hydraulic drive (A) according to claim 1 or 2, characterized by at least one with the electronic control device (10) connected to means (8) for detecting the actual flow in the hydraulic line (L), wherein the control device (10) for automatic Rules of the river in the hydraulic line (L) is set up on the basis of the detected actual flow in relation to a predefinable desired flow.

4. Hydraulic drive (A) according to one of the preceding claims, characterized by at least one hydraulic fluid reservoir (1), which via a hydraulic fluid supply line (1 1) with the hydraulic line (L) is connectable.

5. Hydraulic drive (A) according to claim 4, characterized in that the hydraulic fluid reservoir (1) is provided with a heating and / or cooling unit.

6. A hydraulic drive according to claim 4 or 5, characterized in that the hydraulic fluid reservoir (1) is equipped with a device for filtering the hydraulic fluid.

7. Hydraulic drive (A) according to one of the preceding claims, characterized by at least one with the hydraulic line (L) connectable means (5) for storing of standing under a predetermined pressure hydraulic fluid.

8. Hydraulic drive (A) according to one of the preceding claims, characterized by at least one on the hydraulic line (L) arranged overpressure valve (9).

9. Hydraulic drive (A) according to one of the preceding

Claims, characterized in that the hydraulic pump (2) is combined with at least one device connected to the electronic control device (10) for detecting the flow of the hydraulic fluid.

10. A hydraulic drive (A) according to any one of the preceding claims, characterized in that the electronic control device (10) comprises means for inputting hydraulic fluid target values and / or means for displaying detected hydraulic fluid actual values.

1 1. Hydraulic drive (A) according to one of the preceding claims, characterized in that two or more hydraulic pumps (2) are provided.

12. Hydraulic drive (A) according to claim 1 1, characterized in that the hydraulic pumps (2) differ in their dimensions and / or performance.

13. Hydraulic system with at least one hydraulic actuator, characterized by at least one hydraulic drive (A) according to one of the preceding claims.

14. A method for operating a hydraulic drive (A), which is equipped with at least one electric motor (M) for driving a hydraulic pump (2) and with which the properties of a hydraulic fluid are variable so that it matches the characteristics of at least one with the Hydraulic fluid can be adapted to be supplied to the hydraulic actuator, wherein at least the actual pressure of the hydraulic fluid is detected, the detected actual pressure is compared with a predetermined target pressure, and the electric motor (M) is automatically turned on when the actual pressure is smaller when the target pressure is and is automatically turned off when the actual pressure is equal to or greater than the target pressure.