DE9314760U1 - Start-up circuit - Google Patents

Description

Patent Attorneys Sf

European Patent Attorneys Dipl.lüg. H.Flllk

Dr.-Ing.M.Held Dipl.-Ing. M. Bartels

Authorized representatives Patent attorneys ■ Lange Straße 51 ■ D-70174 Stuttgart at the European Patent Office

24 August 1993 Gm6010/4020

Flutec Fluid Technology Equipment GmbH 66280 Sulzbach

Start-up circuit

The invention relates to a device for facilitating the start-up of an electric motor which is intended for driving a hydraulic pump, whereby the part of a hydraulic circuit leading to an output element is kept essentially pressureless by means of a directional control valve at least when the electric motor starts up.

The electric motors freely available on the market and those provided here, especially if they are intended to be inexpensive, often have a low starting torque, so that it is not possible to start the motor against maximum load, which occurs, for example, when driving a hydraulic pump.

Various options are proposed in the state of the art to increase the starting torque. For example, a so-called starting capacitor is used in a device of a different type for the electric motor, but this involves a high level of technical effort, since in addition to the starting capacitor, a centrifugal switch is also required, which switches off the starting capacitor after the motor has run up to its nominal speed.

Another type of device of a different type uses a so-called operating capacitor with a much higher capacity. Despite this higher capacity, the

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The starting torque generated is not sufficient for all applications, especially in hydraulic circuits. In addition, the price of the capacitor in question is high. The motor also consumes more power due to the use of the operating capacitor, which reduces its service life.

Another possibility for starting assistance could be to first bring the electric motor up to its nominal speed without load and then connect the hydraulic pump to the motor via a coupling device. However, such coupling devices are expensive to purchase and are not wear-free, so such devices involve a corresponding amount of maintenance.

In a generic device to facilitate the start-up of an electric motor, electrically controlled solenoid valves are used for pressure-free circulation in the hydraulic circuit. The electrical control for the motor must then be supplemented to control the solenoid valve, which in turn entails a high level of equipment complexity.

Based on this state of the art, the invention is based on the object of creating a device for facilitating the start-up of an electric motor intended for driving a hydraulic pump, with which it is possible to use even very inexpensive electric motors with a low starting torque, which is inexpensive to manufacture and operates maintenance-free and without disruption. This object is achieved by a device with the features of claim 1.

Because, according to the characterizing part of the claim, the directional control valve can be operated hydraulically and is connected to the hydraulic circuit with a control connection in the fluid direction behind the hydraulic pump, it is possible to start the motor without load. To do this, the directional control valve opens and forms

a kind of "bypass" to the tank. The hydraulic circuit behind the hydraulic pump is then essentially kept pressure-free and the electric motor accelerates towards its nominal speed. The hydraulic pump connected to the motor pumps more fluid as the motor starts up and from a predefined fluid quantity, which is accompanied by a pressure difference in the utility connections in front of and behind the directional or bypass valve, the valve is brought into its closed position via the control connection and the path to the tank is blocked. When the nominal speed of the electric motor is reached, the directional valve closes automatically and the pump flow is directed to the respective hydraulic output element.

As long as the engine is running, the directional control valve remains closed, whereby when the engine is switched off, the pressure in the line to the respective output element between the pump and the control connection is reduced in a defined manner until the valve opens again and creates the "bypass" to the tank for a new engine start.

In a preferred embodiment of the device according to the invention, the directional control valve is a 2/2-way seat or slide valve, whereby the directional control valve has a throttle in a switching position between the two connections A, B. The pressure difference in the service connections A, B in front of and behind the valve can be set using the predeterminable throttle cross-section, which is necessary in order to switch the valve via the control connection of the valve.

In a further preferred embodiment of the device according to the invention, the electric motor is a three-phase motor, in particular a single-phase motor. The single-phase motor is inexpensive to purchase and can be connected to the mains and operated via a mains connection, as is also common in private households, which increases the possible uses of the device according to the invention.

In a particularly preferred embodiment of the device according to the invention, the output element is a hydraulic cylinder of a lifting table, which can be supported in its position via a check valve in the hydraulic circuit. Due to this support via the check valve, the respective output element remains in its current position, even if the electric motor is switched off. Using the device according to the invention, the check valve only opens when the desired pumping power of the hydraulic pump is reached and it is therefore ensured that the output element moves in the desired direction. The control connection of the directional valve between the hydraulic pump and the check valve is preferably connected to the hydraulic circuit.

In a further preferred embodiment of the device according to the invention, a further 2/2-way valve is connected in the hydraulic circuit between the output element and the check valve and parallel to the directional control valve, which is preferably electrically actuated. When the check valve is closed and the engine is turned off, the output element can then be returned to its basic position via this further directional control valve.

In a further preferred embodiment of the device according to the invention, the directional control valve has a leakage connection to the tank of the hydraulic circuit. In particular, if the directional control valve is a directional spool valve, the leakage oil quantities associated with the switching of the valve can be discharged to the tank in a defined manner.

The device according to the invention is explained in more detail with reference to the drawing. The only figure in the drawing shows the basic circuit diagram of the start-up circuit.

The device shown in the start-up circuit diagram serves to facilitate the start-up of an electric motor 10. The electric motor 10 is formed from a single-phase motor with a low starting torque. The single-phase motor 10 is connected in the usual and therefore not described in detail manner to a hydraulic pump 14 via a shaft drive 12. The hydraulic pump 14 takes hydraulic oil from a tank 16 and feeds it into a hydraulic circuit designated as a whole by 18.

The hydraulic pump 14 actuates an output element in the form of a hydraulic cylinder 20, the piston rod 22 of which is connected to a lifting table (not shown) for lifting and lowering loads. The cylinder 20 connected to the hydraulic circuit is supported by a spring-loaded check valve 24, i.e. the lifting table cannot lower itself unintentionally and, under certain circumstances, be dangerous for an operator. In order to keep the hydraulic circuit 18 depressurized, essentially for the start-up of the motor 10, upstream of the check valve 24, a 2/2-way seat or slide valve 26 is provided, which can be brought into its switching position connecting the two utility connections A, B by spring force. The utility connection B is connected via a corresponding line between the hydraulic pump 14 and the check valve 24, whereas the utility connection A is connected via a corresponding line to the tank 16. In its switching position shown in the figure, which connects the utility connections A and B, the flow can be selected via a throttle 28 with a predeterminable throttle cross-section, which is part of the 2/2-way valve 26. A control connection 30 of the directional valve 26 is connected to the line with the utility connection B. The 2/2-way valve 26 also has a leakage line 32 leading to the tank 16.

As the figure shows in particular, between the output element 20 and the check valve 24 and parallel to the directional control valve 26, another 2/2-way valve 34 is integrated in the hydraulic

circuit 18. The additional directional valve 34 is electrically operated and is moved into its closed position shown in the figure by spring support. The drain line 36 downstream of the valve 34 in the fluid direction, into which the utility connection A opens, and the leakage line 32 also lead to the tank 16.

The function of the device according to the invention is explained in more detail below using the figure. In order to enable the motor 10 to start without a load, the valve 26 is in its open position as shown in the figure. In this open position, a type of bypass is provided via the valve 26 and the amount of fluid delivered by the hydraulic pump 14 is conveyed into the tank 16 via the utility connection B, the throttle 28 of the valve 26 and the utility connection A. The motor 10 can therefore reach its intended nominal speed for driving the hydraulic pump 14 without any additional aids despite the low starting torque, which would not be possible if the single-phase motor 10 had to work directly against the maximum load.

As the amount of fluid delivered by the hydraulic pump 14 increases, the flow at the throttle 28 of the valve 26 increases and therefore the pressure difference between the two utility connections A and B, which is tapped via the control connection 30. When a predeterminable value is reached, the valve 26 is then brought into its closed position, which blocks the connection A, B, via the control connection 30 and the pressure in the hydraulic circuit 18 opens the check valve 24 and the piston rod 22 can be extended via the working cylinder 20. As long as the motor 10 is running at the nominal speed, the valve 26 remains closed. If the motor 10 is switched off, the pressure in the line between the pump 14 and the check valve 24 is reduced in a defined manner and the valve 26 opens the bypass to the tank 16 again. A new, essentially load-free engine start is then possible.

If the lifting table is to be lowered with the piston rod 22, the additional directional valve 34 can be brought into its open position electromagnetically and the fluid flowing back from the cylinder 20 is fed to the tank via the drain line 36. Except when the lifting table is lowered (not shown) or when the piston rod 22 is retracted, the valve 34 remains in its closed position shown in the figure.

Providing a hydraulically extendable lifting table as the output element is only one application of the device according to the invention. The device according to the invention can be used for all types of electric motors, in particular three-phase motors; however, use with single-phase motors has proven to be particularly advantageous.

Claims (7)

- Ol - Gm 6010/40 Protection claims: 1. Device for facilitating the start-up of an electric motor (10) which is intended for driving a hydraulic pump (14), whereby the part of a hydraulic circuit (18) leading to an output element (20) is kept essentially pressureless by means of a directional control valve (26) at least when the electric motor (10) is started, characterized in that the directional control valve (26) can be actuated hydraulically and is connected to the hydraulic circuit (18) with a control connection (30) in the fluid direction behind the hydraulic pump (14). 2. Device according to claim 1, characterized in that the directional control valve (26) is a 2/2-way seat or slide valve and that in a switching position between the two connections (A, B) the directional control valve (26) has a throttle (28). 3. Device according to claim 1 or 2, characterized in that the electric motor (10) is a three-phase motor, in particular a single-phase motor. 4. Device according to one of claims 1 to 3, characterized in that the output element (22) is a hydraulic cylinder of a lifting table, which can be supported in its position via a check valve (24) in the hydraulic circuit (18). - 02 - 5. Device according to one of claims 1 to 4, characterized in that the control connection (30) of the directional control valve (26) is connected to the hydraulic circuit (18) between the hydraulic pump (14) and the check valve (24). 6. Device according to one of claims 1 to 5, characterized in that between the output element (22) and the check valve (24) and parallel to the directional control valve (26) an additional 2/2-way valve (34) is connected in the hydraulic circuit (18), which is preferably electrically actuable. 7. Device according to one of claims 1 to 6, characterized in that the directional control valve (26) has a leakage connection (32) to the tank (16) of the hydraulic circuit (18).