WO1997027673A1

WO1997027673A1 - Electronic switching device operating in a contactless manner

Info

Publication number: WO1997027673A1
Application number: PCT/DE1997/000097
Authority: WO
Inventors: Thomas KÖLPIN
Original assignee: Siemens Aktiengesellschaft
Priority date: 1996-01-25
Filing date: 1997-01-21
Publication date: 1997-07-31
Also published as: DE19602681C1

Abstract

The object of the invention is to provide an electronic switching device (10), in particular a proximity switch, which is insensitive to contamination, wear and manipulation by unauthorized persons. This object is achieved in that the switching device (10) comprises a component (12) which can be adjusted in contactless manner by the external magnetic field of an actuator (11) such that the switching device (10) can be adjusted and parametrized thereby.

Description

description

Electronic, non-contact switching device

The invention relates to an electronic, contactlessly operating switching device with a contactlessly adjustable component outside the switching device for setting or parameterization.

A generic switching device is known from DE 43 41 600 Cl. Here, the contactless setting is made via a light-emitting diode serving as a switching status indicator. DE 43 31 555 AI discloses a potted proximity switch with switching point adjustment. For this purpose, a circuit consisting of a counter, a control logic and a

Digital-to-analog converter and a read-only memory connected to the control logic. The circuit enables a controllable voltage divider or a controllable resistor to be automatically set to the value at which the switching state change takes place.

A proximity switch is known from EP 0 519 089 A2, in which the operating parameters can be read in when they are ready for operation. This proximity switch contains an enable input and an overcurrent monitoring device with a microprocessor. By simulating overcurrent conditions, a set value of an operating parameter is signaled to the microprocessor from the outside.

In addition, proximity switches are based on inductive; capacitive, ultrasonic or optical methods are known, in which the required setting is carried out via mechanical, in some cases multi-turn potentiometers, e.g. DE 40 06 893 C2 discloses. Although these potentiometers are relatively cheap and easy to use, they can also be used with one

A number of disadvantages. Initially, potentiometers as mechanical components are prone to failure, especially sensitive to aging, provided with relatively large tolerances and not always available in SMD versions. In addition, the adjustment is sometimes difficult, potting problems occur and complex mechanics are required if a certain degree of protection is to be guaranteed. In addition, mechanical potentiometers are sensitive to wear, their end stops can be easily damaged during operation, unauthorized persons can easily adjust them, and the outer cover of the proximity switch must be broken for operation, which reduces its resistance to harmful substances from the environment. Although part of the disadvantages described can be avoided by setting an electronic device by influencing a reflex light barrier by placing a finger on a hermetically sealed window, unauthorized interventions are still easily possible with this solution. In addition, problems due to window soiling or strong external light can occur.

The invention has for its object to provide an electronic switching device of the above type, in which the setting or parameterization is possible in a simple manner, the above influences being avoided.

The object is achieved in that the component can be adjusted by an external magnetic field of an actuator.

Advantageous embodiments of the invention can be found in the subclaims 2 to 9.

It is particularly advantageous if the adjustable component can be controlled by a controller with a sequence program and, depending on the specification of the drain program, different parameter and setting values can be supplied to the controller via the component. The component is advantageously accommodated in the housing of the switching device, the housing being made of a magnetically penetrable material in the region of the component.

It is furthermore advantageous if coupling means are arranged on the switching device in the area of the component for coupling the actuator, which has a magnet that can be moved for the adjustment, and have a configuration that is suitable for the guided movement of the magnet.

A particularly simple embodiment exists if the housing has a cylindrical shape in the area of the component as coupling means, the bottom of which is magnetically permeable. In addition to the fastening of the actuator, this enables the component to be influenced via the magnetic permeable base.

A likewise advantageous embodiment is obtained if the switching device has two adjustable components, one of which serves to select the parameter to be influenced and a second one to influence the selected parameter.

According to a further advantageous embodiment, the switching device has an optical display device for outputting the setting values.

The component can advantageously serve as a means of communication between the controller and the outside world. By means of the component, the control for distinguishing between an initialization, setting and operating phase can be advantageously influenced.

According to a further embodiment, digital signals can be transmitted by the component, so that access is provided via this In addition to the proximity switch, the partial or complete change of the sequence program in the proximity switch is also possible.

A particularly simple design exists if the component is a magnetically influenceable resistor.

The resistor advantageously works on the basis of the giant magnetoresistive effect.

An embodiment of the invention is explained below with reference to a drawing. Show it:

1 shows a proximity switch according to the invention with separate parameter selection and influencing and alphanumeric display in a spatial representation, FIG. 2 shows an actuator for a GMR resistor and FIG. 3 shows a section of the circuit of the proximity switch with control and connection of GMR resistors and Display.

1 shows an electronic switching device 10 according to the invention in the form of an ultrasonic proximity switch. It essentially has an ultrasound transducer 1, a sleeve 2 with a circuit therein and a cable 6, via which the circuit is supplied and the output signal of the proximity switch can be taken off. In the sleeve 2, two cylindrical depressions 3 and 4 are made as formations, the bottom surface of which consists of magnetically permeable material. Below the recesses 3, 4 there is a magnetically influenceable resistor 12, 16 on the inside of the proximity switch 10, based on the giant magnetoresistive effect (GMR), ie a contactless, magnetically influenceable component. For the structure and operation of such GMR resistors 12, 16, reference is made to the content of DE 43 01 704 AI. For example, the GMR resistor 12 for influencing the parameter selection can be set via the recess 3 and the GMR resistor 16 for influencing the selected parameter via the recess 4. In the housing 2 there is also an alphanumeric display 5, via which selected parameters can be displayed digitally or alphanumerically.

FIG. 2 shows an actuator 11 associated with the setting of the GMR resistors 12, 16, which includes a cylindrical part 7 with a permanent magnet 8, which is followed by an extension 9 designed as a handle. The cylindrical part 7 is provided for use in the correspondingly adapted recesses 3 and 4. The actuator and thus the permanent magnet 8 are rotated via the handle 9, the value of the respective GMR resistor 12, 16 being influenced. Depending on the design of the GMR resistor 16, this influence depends on the angle of rotation with a period of 180 ° or 360 °. If an angle of rotation of 180 ° or 360 ° is not sufficient for the desired resolution, the controller located in the proximity switch 10 must have a counting and storage device for larger angles of rotation.

3 shows a section of the circuit inside the proximity switch 10, which contains a controller 13 with a sequence program 14, the controller being able to be influenced via the connected GMR resistors 12, 16 and via a display device 5 connected to the controller Setting values can be displayed.

A typical setting procedure that can be implemented with the proximity switch 10 according to the invention is explained below.

The proximity switch 10 is supplied electrically via the connecting cable 6 and works with the parameters currently set. In this state, the display device 5 no value displayed. After inserting the actuator 11 into the recess 3, the position of the magnet 8 will generally not match the last position stored by the GMR resistor 12. The value of the GMR resistance 12 thus changes abruptly, as a result of which the parameter selection circuit 15 is activated. If the actuator 11 is accidentally brought into the position stored by the GMR resistor 12, a brief back and forth rotation is sufficient to activate this function. The display device 5 now shows the currently selected parameter. After setting the desired parameter, the actuator 11 is removed from the recess 3. After a delay time, which is predetermined, for example, by the sequence program 14, the display device 5 now shows the current value of the selected parameter. This value can be varied by inserting the actuator 11 into the recess 4. If the actuator 11 is removed or its angle of rotation is not changed further, the set parameter value is adopted in the circuit. The display device 5 switches off again or goes out.

The evaluation of the changes in resistance of the GMR resistors 12, 16 under the recesses 3 and 4 are linked to one another in such a way that the current value of a parameter set via the recess 4 is stored in the proximity switch 10 and by a new actuation can be changed via the recess 4 only after the parameter selection 15 has been run through beforehand. Otherwise, after a parameter had been selected, its previous effective value would not always be read out correctly.

The GMR resistors 12, 16 can generally be seen as communication means between the circuitry of the proximity switch 10 and its surroundings. If digital signals can be transmitted with the GMR resistors 12, 16, a part or the entire sequence program can also be replaced without contact from the outside using this communication means. Although the present invention is explained with reference to the embodiment shown in the accompanying drawing, it should be borne in mind that it is not intended to limit the invention to the embodiment shown, but rather all possible changes, modifications and equivalent arrangements insofar as they are covered by the content of the claims.

Claims

claims

1. Electronic, preferably non-contact switching device (10) with a non-contact adjustable component (12) outside the switching device (10) for setting or parameterization, characterized in that the component (12) is adjustable by an external magnetic field of an actuator (11) is.

2. Electronic switching device according to claim 1, since ¬ characterized in that the adjustable component (12) can be controlled by a controller (14) with a sequence program (15) and, depending on the specification of the sequence program (15), different parameters. and setting values can be fed to the control (13) via the component (12).

3. Electronic switching device according to one of the preceding claims, characterized in that the component (12) in the housing (2) of the switching device (10) is housed, the housing (2) in the region of the component (12) from a magnetically penetrable Material exists.

4. Electronic switching device according to one of the preceding claims, characterized in that on the switching device (10) in the region of the component (12) for coupling the actuator (11), which has a movable magnet for setting (8), coupling means (3,4 ) are arranged which have a configuration suitable for the guided movement of the magnet (8).

5. Electronic switching device according to one of the preceding claims, characterized in that the housing (2) in the region of the component (12) as a coupling means has a cylindrical shape (3,4), the bottom of which is magnetically permeable.

6. Electronic switching device according to one of the preceding claims, characterized in that the switching device (10) has two adjustable components, of which a first (12) for selecting the parameter to be influenced and a second (16) for influencing the selected one Parameter is used.

7. Electronic switching device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the switching device (10) has an optical display device (5) for output of the setting values.

8. Electronic switching device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that by means of the component (12,16), the controller (13) can be influenced to distinguish between an initialization, setting and operating phase.

9. Electronic switching device according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the component is designed as a magnetically influenceable resistor (12,16).

10. Electronic switching device according to claim 9, d a d u r c h g e k e n n z e i c h n e t that the

Resistor (12,16) works on the basis of the giant magnetoresistive effect.