DE4333098A1 - Pressure switch for hydraulic units - Google Patents

Abstract

A pressure switch for a hydraulic reservoir (13) has a tube (10) in which a piston (15) is arranged such that it can be displaced with respect to a spiral spring (16). The piston (15) is coupled to a magnetic sensor (22). Two reed switches (24, 25) are arranged on the outside of the tube (10), such that they can be displaced axially in clamping holders (26). An appropriate position of the reed switches (24, 25) results in the pressure in the hydraulic reservoir (13) always being within predetermined pressure limits. The pressure switch according to the invention is of simple construction and can be produced cost-effectively. <IMAGE>

Description

State of the art

The invention is based on a pressure switch for hydraulic units according to the preamble of claim 1. EP 0 321 376 B1 such a pressure switch is already known. This switches to Ab dependence of pressures a pump, the pressure medium in a tank promotes. For this purpose, the pressure switch has a first magnetic sensor, which is arranged in a consumer line, and which depends on the volume flow to the consumer switches the pump on and off. A second magnetic encoder is attached in line with the first encoder arranges. This is coupled to an adjustable spring on which the hydrostatic pressure prevailing in the tank by means of a membrane acts. If the pressure falls below a certain minimum, be the encoder is in operative connection with a magnetic be actuatable switching element. The pump can be operated manually Increased hydrostatic pressure switched on at minimum pressure become.

A disadvantage of the known pressure switch is that with the spring just a single hydrostatic pressure value, for example a mini painting pressure can be adjusted. The facility is also building  complex and expensive due to the two sensors.

Advantages of the invention

The pressure switch according to the invention for hydraulic units with the kenn Drawing features of claim 1 have the advantage over the other that the hydrostatic pressure in the pressure accumulator between two be arbitrarily selectable pressure limits is controllable. By using it of a single encoder that ge with a piston and a spring is coupled, as well as two inexpensive reed switches fold structure achieved.

Further advantages of the pressure switch according to the invention result from the subclaims and the description. Particularly easy the switching points of the reed switches can be set if these in clamps on the outside of the piston and the Ge Above containing tube arranged in the axial direction are.

drawing

An embodiment of the invention is shown in the drawing represents and is explained in more detail in the following description. Show it

Fig. 1 a pressure switch for hydraulic units simplified longitudinal section, and Fig. 2 shows a part of the pressure switch of Fig. 1 schematically in a perspective view.

Description of the embodiment

The pressure switch for hydraulic units has a hollow cylindrical, non-magnetic tube 10 , for example made of plastic, which is screwed with an extension 11 into an opening 12 in the outer wall of a hydraulic accumulator 13 . However, it is also possible to connect the pressure switch to the hydraulic accumulator 13 by means of a pressure line. In the interior of the tube 10 , the extension 11 has an annular shoulder 14 which serves as a stop for a piston 15 . The piston 15 rests on a spiral spring 16 , which in turn is supported on the end face of a sleeve 17 which is fitted in the tube 10 . On the extension 11 opposite the end, the tube 10 of the pressure switch is closed with a cover 18 ver, which has a drain port 19 .

The piston 15 is connected by means of a piston rod 21 , which also serves as a guide for the spiral spring 16 , with a magnetic Ge 22 . The encoder 22 , which is designed for example as a permanent magnet, is slidably guided in the sleeve 17 .

In the area of the sleeve 17 two reed switches 24 , 25 are seen on the outer wall 23 of the tube 10 with seen in the axial direction of the tube 10 from a. The reed switches 24 , 25 each have a pair of metallic contact tongues 27 , 28 which are arranged to overlap one another. The contact tongues 27 , 28 can attract and touch each other in a conventional manner as soon as they enter the magnetic field of the encoder 22 . The two reed switches 24 , 25 are connected via cables 29 to an electrical control device, not shown, which switches a pump, not shown. The pump conveys pressure medium into the hydraulic accumulator 13 .

The circuit of the electrical control device is such that the first reed switch 24 facing the piston 15, when the contact tongues 27 are closed, enables a current to flow in the cable 29 , which triggers a corresponding pulse in the control device for switching on the pump. The second reed switch 25 triggers a pulse to switch off the pump in the control device when the contact tongues 28 are closed.

The two reed switches 24 , 25 are arranged individually on the circumference of the tube 10 offset from each other non-magnetic clamp holders 26 slidably ver. The clamp holders 26 , like the tube 10, are made of plastic and are molded onto the latter.

Characterized in that each of the reed switches 24 , 25 can be moved within a certain range extending in the axial direction of the tube 10 , two different pressure values for the hydraulic accumulator 13 can be individually set or adjusted accordingly.

The pressure switch for hydraulic units according to the invention works as follows:

According to the hydrostatic pressure in the hydraulic accumulator 13 and the spring force of the spiral spring 16 , a defined position of the piston 15 in the tube 10 , and thus also of the magnetic transmitter 22 in the sleeve 17 , is established. In order to ensure that the pressure in the hydraulic accumulator 13 is always fluctuates between an upper and a lower pressure value, have the two reed switches 24 are positioned 25 in the terminal holders 26 so that the position of the first reed switch 24 to the lower pressure value in hydraulic accumulator 13 corresponds, while the position of the second reed switch 25 is assigned to the upper pressure value.

If there is no pressure in the hydraulic accumulator 13 , the spiral spring 16 presses the piston 15 against the annular shoulder 14 in the tube 10 , and the first reed switch 24 is outside the magnetic field of the transmitter 22 . If, for example, the pump is now switched on automatically or manually for start-up, this pressure medium conveys into the hydraulic accumulator 13 , whereupon its hydrostatic pressure rises. As a result, the pressure acting on the piston 15 against the force of the spiral spring 16 also increases , and the transmitter 22 is moved in the direction of the reed switches 24 , 25 . As soon as the contact tongues 27 of the first reed switch 24 reach the area of influence of the magnetic field of the sensor 22 , they touch, whereupon a current flows in the line 29 . The pulse generated in the control device to switch on the pump has no effect in this case, however, since the pump is already switched on. If the pressure in the hydraulic accumulator 13 continues to rise, the transmitter 22 moves in the direction of the second reed switch 25 . The contact tongues 27 of the first reed switch 24 open again as soon as the magnetic field of the encoder 22 no longer acts on the contact tongues 27 . If the upper pressure value determined by the position of the reed switch 25 is reached, its contact tongues 28 are attracted by the magnetic field of the transmitter 22 , whereupon a corresponding pulse is generated in the control device for switching off the pump.

If pressure medium is now removed from the hydraulic accumulator 13 by a consumer, the hydrostatic pressure in it drops, and the transmitter 22 moves accordingly in the direction of the second reed switch 25 to the first reed switch 24 . As soon as the magnetic field of the sensor 22 no longer acts on the reed switch 25 , its contact tongues 28 open again. If the transmitter 22 reaches the area of the first reed switch 24 in the event of a further pressure drop in the hydraulic accumulator 13 , its contact tongues 27 touch again and, as shown above, the pump consequently conveys pressure medium into the hydraulic accumulator 13 again .

Characterized in that the two reed switches 24 , 25 are arranged offset to one another on the circumference of the tube 10 , the distance a, and thus the upper and lower pressure values can be set very closely to one another, so that a very sensitive control of the hydrostatic pressure in Hydraulic accumulator 13 can be achieved.

Claims (6)

1. pressure switch for hydraulic units (13), coupled to an impinged against the spring force of a spring (16) by the hydrostatic pressure of the hydraulic unit (13) pressure receiving member (15) and with a with the pressure-receiving member (15), a magnetic field generating transmitter element (22 ) which is arranged axially displaceably along at least one magnetic field sensitive switching element ( 24 , 25 ) for actuating a pressure generator, characterized in that the pressure receiving element is a piston ( 15 ) slidingly guided in a tube ( 10 ), that a first switching element ( 24 ) to control a first switching function of the pressure generator, that a second switching element ( 25 ) is used to control a second switching function of the pressure generator, and that the switching elements ( 24 , 25 ) are axially separated and slidably arranged. 2. Pressure switch for hydraulic units ( 13 ) according to claim 1, characterized in that the switching elements are reed switches ( 24 , 25 ). 3. Pressure switch for hydraulic units ( 13 ) according to claim 1 or 2, characterized in that the reed switches ( 24 , 25 ) are arranged in clamp holders ( 26 ). 4. Pressure switch for hydraulic units ( 13 ) according to one of claims 1 to 3, characterized in that the clamp holder ( 26 ) on the order of the tube ( 10 ) are arranged offset to one another. 5. Pressure switch for hydraulic units ( 13 ) according to one of claims 1 to 4, characterized in that the tube ( 10 ) connects directly to the hydraulic unit ( 13 ). 6. Pressure switch for hydraulic units ( 13 ) according to one of claims 1 to 5, characterized in that the tube ( 10 ) and the clamp holder ( 26 ) consist of plastic.