EP1065379A2 - Electrohydraulic pressure supply with variable displacement pump and controllable electric drive - Google Patents

Abstract

The electrohydraulic pressure supply has an electric drive motor (M) with an adjustable rpm (n), a variable displacement pump (1), whose stroke volume (V) can be adjusted by an adjustment component (5) and supply pipes (3) and connections (4). A regulator (Reg) controls the rpm. A control (Strg) controls a pump adjuster (PV) that controls the adjustment component. The regulator has the actual volume flow (Qist) determined by a unit (Q) and the desired volume flow (QSoll) as inputs. The control has the pressure difference ( DELTA p) measured between the supply and suction pipes of the pump and a reference pressure (pref) as inputs.

Description

The invention relates to a device according to the preamble of the independent claim.

Electrohydraulic pressure supplies have found a variety of applications. They are used in electrohydraulic control devices, in hydraulic ones Lifting and lowering loads, when operating hydraulic actuators and not most recently in automotive hydraulics. In automotive hydraulics have electro-hydraulic Pressure supplies e.g. Used in power steering and in electro-hydraulic actuated actuators. To control the volume flow delivered by the hydraulic pump So far, three different principles have been followed.

In a known control principle, the delivery rate is one with an electric motor driven hydraulic pump controlled by regulating the speed of the electric motor becomes. In these systems, the electric motor is operatively connected to the hydraulic pump and the volume flow delivered by the hydraulic pump depends on the speed of the electric drive motor. The hydraulic pump itself has except through the Speed of the drive via no control systems with which the delivered volume flow can be influenced. When designing these systems are attached to the electric drive motor very high demands. The drive motor must be able to both Process large volume flows with small load side system pressures as well small volume flows with high load-side system pressures. The volume flow promoted is proportional to the speed of the drive motor, while the load-side system pressure is proportional the torque applied by the engine. This leads to the drive motors in these electrohydraulic systems both on high speed and on a high torque must be designed. This makes the electric drive motors complex and expensive.

Therefore, electro-hydraulic systems have been proposed in which the electric drive is operated at constant speed. This enables the optimization of the electric motor towards a speed. Because the electric motor is the most complex component of electrohydraulic Systems can be optimized by optimizing the electric motor constant speed towards cost advantages. The required volume flow of the hydraulic pump is set by regulating a by-pass valve. This principle of regulation assumes that the pump constantly delivers at least the set volume flow. Since the Target volume flow must also be made available if there is no hydraulic power these systems have a relatively high unused power loss.

In motor vehicles in particular, the power that can be drawn from the electrical system is electrical Pump drive limited. That is why higher performance is required for hydraulic pumps mechanical drives used e.g. via a belt drive or chain drive to the Internal combustion engine of the motor vehicle are coupled. The drive speed of the pump is thereby coupled to the speed of the internal combustion engine and not controllable independently. In these systems, the volume flow delivered is regulated by means of an adjustment of the swallowing volume of the connected hydrate pump. Depending on one System pressure controls the absorption volume of the pump. A disadvantage of these Systems is that the volume flow conveyed depends on the speed of the internal combustion engine depends. Because the necessary system pressure even at low engine speeds In these systems, pumps must be provided relatively large maximum swallowing volume can be used. At high speeds the On the other hand, the internal combustion engine must have the swallowing volume as small as possible can be set, otherwise the system pressure will rise to unpredictably high values would. Therefore, in these systems, the swallowing volume of the pump must be over one relatively large range adjustable, resulting in large mechanical designs for the variable displacement pumps leads.

The object of the invention is therefore to provide an electrohydraulic pressure supply with an adjustable one Specify pump and variable speed drive, which is both optimization of the electric drive as well as the optimization of the adjustable pump with regard to Allows minimizing the necessary component sizes.

According to the invention, this object is achieved by the features of the independent claim. Further advantageous embodiments are contained in the subclaims.

The invention consists in the interaction of two independently adjustable Energy converter and that through a speed-adjustable electric motor, which is a variable displacement pump drives and a variable displacement pump with variable absorption volume. The electric motor converts electrical power consisting of voltage U and current I (lossy) into mechanical Power in speed n and torque T um. The pump is changing (also lossy) convert this mechanical power into hydraulic power. The hydraulic Power is determined by the pressure difference Δp and the volume flow Q. Die Pressure difference Δp is usually impressed on the system by the consumer. The volume flow Q results from the swallowing volume and the engine speed n. The torque T that the motor has to apply results from the swallowing volume V and Pressure difference Δp. When converting hydraulic power into mechanical power the swallowing volume V determines the distribution of the power to the engine speed n and the torque T. The current I flowing in the electric motor is predominantly by determines the torque T, the voltage U is mainly determined by the engine speed n influenced. Size and electrical losses in the electric motor are essentially determined by the maximum torque T required by the motor, ie by the current I. The conveyed volume flow of the electrohydraulic pressure supply is in the essentially set via the speed adjustment of the regulated electric motor. The The speed of the electric drive motor is largely independent of that Adjustable pump suction volume. Largely independent means that for the Setting the speed and the swallowing volume only the specified time currently required target volume flows and reference pressures must be observed. The speed of the drive motor can be completely independent within these two system specifications of the displacement volume of the variable pump. This allows the Displacement volume adjustment of the variable pump can be pressure controlled and by the Adjustment of the swallowing volume changed delivery capacity of the pump by the independent Speed control of the electric motor can be compensated. The acquisition of the volume flow can both directly via a volume flow measuring device and indirectly from the reaction of the working machine, e.g. from the travel range of the connected Actuator. This makes it possible to use the variable displacement pump as a device for influencing the torque e.g. to operate as a torque controller for the electric motor.

The main advantages of the invention are as follows:

The hydraulic power is determined by the pressure difference Δp and the volume flow Q. The volume flow Q is influenced by the engine speed n of the engine and by the displacement volume V of the variable pump. According to the invention, the combination delivers a variable speed drive motor with a variable displacement pump V two degrees of freedom to influence hydraulic performance. This enables with Advantage, the power consumption by the electric motor to the required hydraulic Adapt performance. The destruction of work done in by-pass lines thereby advantageously avoided.

Another advantage of the combination according to the invention is the fact that the required Differential pressure Δp largely independent of the torque T of the electric motor can be. The speed n together with the set swallowing volume V of the variable pump influences the differential pressure Δp. This is used to advantage to limit the maximum torque T that the electric motor must provide. It is more advantageous to have an electric motor with high speed and low torque run to deliver the same power as a low speed electric motor and let great torque run. That determines with engines Torque the component size and thus the cost of the system. The variable displacement pump used as a device for influencing torque e.g. enabled as a torque controller with advantage a torque limitation and thus a smaller drive motor that is optimal and operated with little loss.

Another advantage of the combination of speed-controlled drive according to the invention and variable displacement pump is that such an electrohydraulic Pressure supply with unchanged power consumption both high pressure differences Δp at small volume flows Q as well as large volume flows Q with small pressure differences Can produce Δp. On the one hand, examples of such operating states are highly dynamic Adjustment movements and on the other hand holding functions under load. Such operating states occur in motor vehicles e.g. with active chassis, electro-hydraulic brakes and steering on. Electrohydraulic actuators for these systems can be used with the invention Pressure supply works more economically and is built smaller, lighter and cheaper become.

When using the electro-hydraulic pressure supply according to the invention in motor vehicles there is another advantage. The already described possibility of Torque limitation has beneficial effects on the control and power electronics. The torque T of the electric motor is essentially proportional to the current I. With a torque limitation, the current I is also limited. With that, too the control and power electronics are designed for smaller currents. There The losses in the control and power electronics are also determined by the current are determined, the pressure supply according to the invention also enables the optimum Design and low-loss operation of the control and power electronics.

Fig.1

Eine schematische Darstellung der erfindungsgemäßen Elektrohydraulischen Druckversorgung.

Fig. 2

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für reversierbare Systeme mit einer Pumpenverstellung durch einen elektrischen Aktuator

Fig. 3

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für reversierbare Systeme mit einer Pumpenverstellung durch einen Steuerkolben mit Druckregelventil

Fig. 4

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für reversierbare Systeme mit einer Pumpenverstellung durch einen Steuerkolben und ein elektrisch betätigtes 4-3-Wege-Ventil

Fig. 5

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für reversierbare Systeme mit einer Pumpenverstellung durch einen systemdruckbeaufschlagten Steuerkolben mit Feder

Fig. 6

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für nicht reversierbare Systeme mit einer Pumpenverstellung durch einen elektrischen Aktuator

Fig. 7

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für nicht reversierbare Systeme mit einer Pumpenverstellung durch einen Steuerkolben mit Druckregelventil

Fig. 8

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für nicht reversierbare Systeme mit einer Pumpenverstellung durch einen Steuerkolben und elektrisch betätigtes 4-3-Wege-Ventil

Fig. 9

Eine Prinzipdarstellung eines erfindungsgemäßen Ausführungsbeispiels für nicht reversierbare Systeme mit einer Pumpenverstellung durch einen systemdruckbeaufschlagten Kolben mit Feder

Embodiments of the invention are illustrated below with reference to drawings and explained in more detail. Show it:

Fig. 1

A schematic representation of the electrohydraulic pressure supply according to the invention.

Fig. 2

A schematic representation of an embodiment of the invention for reversible systems with a pump adjustment by an electrical actuator

Fig. 3

A schematic representation of an embodiment of the invention for reversible systems with a pump adjustment by a control piston with a pressure control valve

Fig. 4

A schematic representation of an embodiment of the invention for reversible systems with a pump adjustment by a control piston and an electrically operated 4-3-way valve

Fig. 5

A schematic representation of an exemplary embodiment according to the invention for reversible systems with a pump adjustment by means of a control piston under spring pressure

Fig. 6

A schematic representation of an embodiment according to the invention for non-reversible systems with a pump adjustment by an electrical actuator

Fig. 7

A schematic representation of an embodiment of the invention for non-reversible systems with a pump adjustment by a control piston with a pressure control valve

Fig. 8

A schematic representation of an embodiment of the invention for non-reversible systems with a pump adjustment by a control piston and an electrically operated 4-3-way valve

Fig. 9

A schematic representation of an exemplary embodiment according to the invention for non-reversible systems with a pump adjustment by means of a spring-loaded piston

1 shows a schematic illustration of an electrohydraulic pressure supply according to the invention. An electric motor M is operatively connected as a drive motor to a variable displacement pump 1. The speed n of the electric motor M can be regulated by a regulator Reg. A change in the speed of the electric motor is transmitted to the variable displacement pump 1 via the operative connection 2. The control Reg processed as input variables _to a predetermined value Q for the required target flow rate and a measured value Q _is for the respectively actually conveyed current flow rate of the variable displacement pump. The current volume flow is determined using a device Q for determining the delivered volume flow. The determination of the current volume flow can be carried out directly with a volume flow sensor, or determined indirectly from the reaction of the connected work machine. The connecting lines 3 end with the consumer connections 4. One or more hydraulic actuators and one or more hydraulic storage containers can be connected to the consumer connections 4 on the system side. Exemplary embodiments for the connection of an actuator are shown in FIGS. 2 to 9. Between the connections 4, the differential pressure Δp between the delivery line and the suction line of the variable displacement pump is detected with a pressure measuring device. The differential pressure Δp controls the displacement volume V of the variable pump depending on a reference pressure p _Ref . For this purpose, the differential pressure Δp and the reference pressure p _{Ref are} entered into a control Strg. The control Strg controls the pump adjustment PV, which is in operative connection with the adjustment element 5 of the adjustment pump 1. A change of the absorption volume affects the delivered volume flow Q. The regulation Reg fits over the rotational speed n of the delivered volume flow Q _is the required Q Volumnestrom _intended to. As an alternative to direct measurement, the volume flow can also be determined by determining the travel of the adjusting element 5 and the working speed of the variable pump, for example the speed n. The pump operates below a limit torque defined by p _Ref like a constant unit with a maximum absorption volume. The variation of the electric motor speed n modulates the volume flow (including reversing). If the limit torque is exceeded, the control reduces the absorption volume until the limit torque is applied as the load torque. The torque is measured indirectly via the motor current or the differential pressure Δp. The requested volume flow Q _should be made available with a reduced swallowing volume by increasing the engine speed.

Fig. 2 shows a schematic diagram of an embodiment according to the invention for reversible Systems with a pump adjustment by an electrical actuator. To the Pump connections 4, a hydraulic actuator 6 and a pressure reservoir 7 are connected. The adjusting member 5 of the variable pump 1 is equipped with an electric actuator 8 operated. The actuator is controlled by the control Ctrl.

Fig. 3 shows a schematic diagram of an embodiment according to the invention for reversible Systems with a pump adjustment by a control piston with pressure control valve. In this exemplary embodiment, a control piston 9 changes the position of the adjusting member 5 the pump 1. The control piston 9 is always connected to the pressure side, which guarantees a pressure-controlled 4/3-way valve 10. A spring 11 pivots the actuator 5 at 0 pressure maximum swallowing volume and delivers a path-proportional counterforce under pressure. about an electrically controlled valve for pressure regulation 12, e.g. a pressure control valve, can at Pressurization, the piston force of the control piston 9 can be set. The control of the valve for pressure control 12 takes place via the control Ctrl. In connection with the Spring force of the piston spring 11 results in a piston position.

Fig. 4 shows a schematic diagram of an embodiment according to the invention for reversible Systems with a pump adjustment by a control piston and an electric actuated 4-3-way valve. In this embodiment, a differential spool changes 9 the position of the actuator 5 of the pump 1. An electrically controlled 4/3-way valve 13 ensures the pressurization of the respective piston surface of the differential control piston 9. The piston position is determined by the opening time of the 4/3-way valve 13 regulated. The middle position of the valve blocks the oil flow and fixes the piston in it Location. The valve is controlled via the control Ctrl. A pressure controlled 4/3-way valve 10 ensures the direction of the control pressure gradient. The dynamics of the adjustment depends on the height of the pressure drop.

5 shows a basic illustration of an exemplary embodiment according to the invention for reversible systems with a pump adjustment by means of a control piston with spring which is pressurized to the system. In this exemplary embodiment, a control piston 9 changes the position of the actuator 5 of the pump 1. The control piston 9 is always connected to the pressure side via the connections 4 and the 4/3 way valve 10. A spring 11 pivots the actuator 5 to maximum absorption volume at 0 pressure and delivers a path-proportional counterforce under pressure. The path of the control piston is proportional to the pressure drop. If the spring 11 is installed with preload, the system only regulates when a limit pressure drop p _{ref is} exceeded. The limit pressure drop p _Ref is predetermined by the preload of the spring 11. The parallel connection of differently long and / or differently rigid springs 11 or the use of stepped pistons change the control characteristic of the control piston 9. Since the load torque is approximately pressure-proportional, the differential pressure Δp between the two connections 4 can be used as a control variable. The advantage of this embodiment lies in its passive self-regulation by the spring 11. An active regulation of the control piston 9 by an active control can be dispensed with.

6 shows a basic illustration of an exemplary embodiment according to the invention for reversible systems with a pump adjustment by an electric actuator. In In contrast to the exemplary embodiment according to FIG. 2, this exemplary embodiment is the Pump 1 cannot be reversed. Another difference to Fig. 2 is the fact that the Storage container 14 is not a pressure storage container, but only a pressureless storage container for the hydraulic fluid for actuating the hydraulic actuator 6. The adjusting member 5 of the pump 1 is actuated by the electrical actuator 8. The actuator 8 will controlled by the control Ctrl.

7 shows a basic illustration of an exemplary embodiment according to the invention for reversible systems with a pump adjustment by a control piston with pressure control valve. A control piston changes the position of the adjusting element as shown in Figure 11 Pump. The control piston 9 is connected to the pressure side of the pump 1 via the pump connection 4 connected. A spring 11 pivots the actuator 5 of the pump 1 to the maximum at 0 pressure Swallowing volume and provides a path-proportional counterforce under pressure. About an electric controlled valve for pressure regulation 12, e.g. a pressure control valve, can when pressurized the piston force can be adjusted. The valve is controlled via the Control Ctrl. The piston position results in connection with the spring force.

8 shows a basic illustration of an exemplary embodiment according to the invention for reversible systems with a pump adjustment by a control piston and an electric actuated 4-3-way valve. In this embodiment, a differential changes Control piston 9, the position of the actuator 5 of the pump 1. An electrically controlled 4/3-way valve 13 ensures that the respective piston surface is pressurized. The piston position is regulated via the opening time of the valve 13. The middle position of the valve blocks the oil flow and fixes the piston in position. The valve is controlled via the control Ctrl. The dynamics of the adjustment depend on the height of the pressure drop between the two connections 4.

9 shows a basic illustration of an exemplary embodiment according to the invention for non-reversible systems with a pump adjustment by means of a piston with spring which is pressurized to the system. In this exemplary embodiment, a control piston 9 changes the position of the actuator 5 of the pump 1. The control piston 9 is connected to the pressure side of the pump 1. A spring 11 pivots the actuator 5 to maximum absorption volume at 0 pressure and delivers a path-proportional counterforce under pressure. The path of the control piston corresponds to the pressure drop. If the spring 11 is installed with preload, the system only regulates when a limit pressure drop p _{ref is} exceeded. The limit pressure drop p _Ref is predetermined by the preload of the spring 11. The parallel connection of differently long and / or differently stiff springs 11 or the use of stepped pistons in the control piston 9 change the control characteristic. Since the load torque is approximately pressure-proportional, the differential pressure Δp between the two connections 4 can be used as a control variable.

Claims (11)

Electrohydraulic pressure supply with a speed-controllable electric drive motor (M) and a variable displacement pump (1), the absorption volume (V) of which can be changed by an adjusting element (5), comprising connecting lines (3) and consumer connections (4) a control (Reg) for speed control of the drive motor (M) and a device (Q) for determining the delivered volume flow (Q _ist ), the control (Reg) at least the delivered volume flow (Q _ist ) and a set volume flow (Q _soll ) as Has input variables, a pump adjustment (PV) for actuating the adjustment member (5) of the adjustment pump (1) and a control (Strg) for controlling the pump adjustment (PV) and a pressure measuring device (Δp) for determining the differential pressure (Δp), the control (Strg) has at least one reference pressure (p _Ref ) and the differential pressure (Δp) as input variables. Apparatus according to claim 1, characterized in that the speed (s) of the drive motor (M) essentially independent of the adjustment of the swallowing volume (V) of the variable pump (1) is adjustable. Device according to claim 1 or 2, characterized in that the variable displacement pump (1) can be operated as a device for influencing the torque of the drive motor (M). Device according to one of claims 1 to 3 for reversible systems with a hydraulic Actuator (6) and a pressure reservoir (7), characterized in that the pump adjustment (PV) is an electrical actuator (8). Device according to one of claims 1 to 3 for reversible systems with a hydraulic Actuator (6) and a pressure reservoir (7), characterized in that the pump adjustment (PV) from a valve for pressure regulation (12), a control piston (9) with at least one spring (11) and a hydraulically operated 4-3-way valve (10) exists. Device according to one of claims 1 to 3 for reversible systems with a hydraulic Actuator (6) and a pressure reservoir (7), characterized in that the pump adjustment (PV) from a differential control piston (9), a hydraulic operated 4-3-way valve (10) and an electrically operated 4-3-way valve 13. Device according to one of claims 1 to 3 for reversible systems with a hydraulic Actuator (6) and a pressure reservoir (7), characterized in that the pump adjustment (PV) from a control piston (9) with at least one spring (11) and a hydraulically operated 4-3-way valve (10). Device according to one of claims 1 to 3 for non-reversible systems with a hydraulic actuator (6) and a reservoir (14), characterized in that the pump adjustment (PV) is an electrical actuator (8). Device according to one of claims 1 to 3 for non-reversible systems with a hydraulic actuator (6) and a reservoir (14), characterized in that the pump adjustment (PV) from a valve for pressure regulation (12) and a control piston (9) with at least one spring (11). Device according to one of claims 1 to 3 for non-reversible systems with a hydraulic actuator (6) and a reservoir (14), characterized in that the pump adjustment (PV) from a differential control piston (9) and an electric operated 4-3-way valve (13). Device according to one of claims 1 to 3 for non-reversible systems with a hydraulic actuator (6) and a reservoir (14), characterized in that the pump adjustment (PV) from a control piston (9) with at least one spring (11) consists.

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