DE19902723C1 - Electrical switch for non-contact position scanning of a mechanically movable ferromagnetic part e.g. for vehicle safety belt locks, has slide plate sliding on contact carrier and contact fingers - Google Patents

Abstract

Sliding on a contact carrier (12), a slide plate (26) has contact fingers (38) to produce electrically conductive contacts alternately with a preset combination of switch surfaces on the contact carrier in the slide plate's end position. A permanent magnet (28) fixed to the slide plate and attracted to a ferritic operating part positioned in its magnetic field shifts the slide plate into a contact end position.

Description

The invention relates to an electrical switch for contactless position detection ge for a mechanically movable ferromagnetic part, the movable part acts on a magnetic sensor that triggers an electrical signal when activated.

Such contactless position queries of moving parts are versatile if a secure query of the locking position of a locking element is desired is worthwhile. Possible applications can be door locks, in which one automatically engages when the bolt engages in the striking plate Alarm system should be armed. Such position queries are also of the lock elements for example for washing machines with front loaders or for pyrolysis locks conceivable with ovens. Another known application of such electrical Switches for contactless position detection are also available with mechanical ones Belt buckles for the safety belt in motor vehicles are known (US Pat. No. 5,742,986 and 5 752 299), whereby for the position query of the blocking element with magnets cooperating Hall sensors are used when engaging the Verrie gelungselementes trigger an electrical signal in the lock tongue. This electri cal signal can be used to control the airbag Belts or other visual displays are used.

Basically, such position queries result in a secure locking the locking element must not be endangered, so that a direct actuation of the electrical switch through the locking element to the switch with the actuation force must be avoided. Such a desired touch Loose actuation of the electrical switch is possible through the use of Hall sensors ren according to US-A-5 742 986 and 5 752 299 possible.

In particular, the present invention relates to an electrical switch for non-contact switching with a ferromagnetic actuator  the preamble of claim 1. Such an electrical switch is such. B. from the DE-AS-11 60 055 known.

The invention has for its object to touch an electrical switch position detection for a mechanically movable ferromagnetic part to create according to the preamble of claim 1, with depending on need different electrical switching functions can be triggered.

This task is invented for an electrical switch of the type mentioned in the introduction solved according to the invention in that a contact carrier with several electrical buttons and with external electrical connection files is mounted fixed; that a slide plate on the contact carrier ver is slidably arranged and provided with contact fingers, the contact fingers in the respective end position of the slide plate with a predetermined combination of. Buttons alternately create electrically conductive connections; that with the Slider plate is permanently connected to a permanent magnet, which in response to the ferromagnetic actuator positioned in its magnetic field is attracted and moves the slide plate into a contact end position; and that one between the slide plate and the permanent magnet arranged spring with the elimination the action of the ferromagnetic actuator the slide plate in its off shifted backwards gear position.

With such an electrical switch it is advantageously achieved that by the contactless action of the ferromagnetic actuator on the with the slide plate connected permanent magnet the slide plate in two end position is shiftable, depending on the design of the contact finger arrangements in the slide plate with for the respective desired application suitable contact tongues on the contact carrier comes and emits appropriate electrical signals. The electrical switch can be in simple way in its mechanical design on the respective application be trained case so that it takes up little space and as completed separate unit can be used in a lock body, in which a fer Romagnetic actuator is used as a lock.

To the spring to move back the slide plate after actuation of the Arranging the switch as space-saving as possible is for a special embodiment  the invention provided that between the permanent magnet and the slide plate in this a recess is made in which out as a compression spring formed spring between the slide plate on the one hand and one in the recess ra the spring holder on the contact carrier is clamped on the other hand. This leaves the relative movement required for the electrical contact between the  Design the contact carrier and the slide plate in a simple manner.

A special embodiment of the contact carrier provides that the contact tongue trained buttons part of an integrated in the contact carrier Are stamped grids, the individual contact tongues having a roof-shaped shape are provided on the opposite, obliquely extending Buttons alternately in the contact fingers provided in the slide plate the respective end position of the slide plate come to rest.

The invention further provides that the contact fingers are also part of one in the shooting Top plate are integrated lead frames, and that the front end of the contact finger according to the sloping features of the contact tongues are. Due to this configuration, the contact fingers according to the invention Slider plate positioned so that it only shortly before reaching the the end positions of the slide plate sliding with the contact tongues in Be come touch.

Finally, it is also provided that the contact fingers at the upturned ends are provided with stamped spherical caps.

The lead frame with the contact tongues is for secure mounting and contacting positively integrated in the contact carrier.

The invention further provides that the lead frame with the contact fingers in one is injected over the contact tongues open frame of the slide plate. Thereby can be advantageously by the design of the lead frame, in the the injection into the frame connecting webs between the individual contacts fingers are punched out according to the desired contact assignment electrical switches in a simple manner to the required switching conditions adjust gene.

In order to securely attach the permanent magnet to the slide plate, it is provided that that this is embedded in the front end of the slide plate by injection molding. The magnet can point to the ferromagnetic actuator The face is exposed or covered with a thin layer of plastic. The complete encapsulation of the permanent magnet also offers the advantageous Possibility of realizing a watertight switch if at the same time the off acceptances  for receiving the connection contacts after contacting them with the connection line tungen, d. H. the assembly opening in the housing after assembly with synthetic resin is poured.

A special embodiment of the invention provides that the electrical switch to query the locking function of the locking segment of a mechanical belt buckle is used for motor vehicles, the locking element being a ferromagnetic Is part and serves as an operating part for the electrical switch.

The advantages and features of the invention also result from the following Description of an embodiment in connection with the claims and the Drawing. Show it:

Figure 1 shows the electrical switch according to the invention in an exploded view.

2 shows a longitudinal section through the switch in the rest state.

Fig. 3 shows a longitudinal section through the switch in the actuated state.

An electrical switch according to the invention is shown in FIGS. 1 to 3, the same parts being provided with the same reference numerals in all the illustrations.

The electrical switch consists of a housing 10 which is provided on one end face with egg ner mounting opening 11 , into which the parts forming the switch can be inserted after assembly. The actual switch consists of a con tact carrier 12 which carries a spring holder 16 at the front end of a tongue-shaped extension 14 . On the side opposite this spring holder, holders for contact tongues 18 are provided, which are made from a lead frame and are inserted with their connecting contacts 19 into recesses 20 at the rear end of the contact carrier 12 . In the same recesses, electrical connection line 22 are also introduced and their conductors are connected to the connection contacts 19 . Roof tongues 24 are brought to the contact tongues 18 , the oblique flanks of which form the actual buttons.

On the contact carrier 12 a slide plate 26 is arranged longitudinally displaceable, which carries at its front ends an injected into the slide plate 26 permanent magnet 28 . In the slide plate 26 , a recess 30 is then provided on the permanent magnet 28 , into which engages the spring holder 16 after assembly of the slide plate with the contact carrier, which is opposite a spring holder 17 attached to the slide plate. Between these in the spring mounts a compression spring 32 is used, which can be more or less tensioned by a Relativver shift between the slide plate and contact carrier.

The slide plate 26 is at the opposite end of the permanent magnet 28 from a frame 34 , in which a lead frame 36 is injected, on which chem the contact fingers 38 are formed. Depending on the number of adjacent contact tongues 18 in the contact carrier 12 , more or fewer contact fingers 38 are provided for the desired switching function. These contact fingers 38 can initially be connected to the frame of the lead frame by means of webs, which, however, can be eliminated by punching out after injection into the slide plate. Depending on the desired switching function, it may also be necessary to separate the individual contact fingers in the frame area, which is also done by punching out connecting webs. Two such Tren openings of the frame are shown in the drawing, the connecting webs are already removed. These connecting webs are punched out after the injection of the punched grid into the frame 34 in the region of a bore 39 or a recess 40 .

The front free ends 42 of the contact fingers 38 are edged obliquely in accordance with the course of the buttons of the roof-shaped features 24 on the contact tongues 18 and provided on the contact side with spherical caps which rest on the roof-shaped features when contact is made.

The injected permanent magnet 28 is preferably embedded on all sides in the slide plate 26 . If, in this case, the assembly opening 11 is potted in a conventional manner with synthetic resin after the final assembly, a watertight electrical switch is obtained. As a result, the area of application for the switch is considerably increased.

The operation of the switch is described with reference to FIGS. 2 and 3.

As can be seen from the two drawings, the contact carrier 12 is fixed in the housing 10 , the fixing being achieved in that the recesses 20 and the mounting opening 11 are filled with synthetic resin after assembly. This synthetic resin composition thus also encloses the front ends of the electrical lines 22 .

The slidably arranged on the contact carrier 12 slide plate 26 engages with its spring holder 17 in the recess 31 of the contact carrier 12 , the Fe derhalterung 17 of the spring holder 16 on the contact carrier 12 opposite. The compression spring 32 is inserted between these two spring holders, the spring holder 17 coming into contact with the right end face of the recess 31 in the contact carrier 12 in a rest position shown in FIG. 2. In this position, the left-hand contact fingers 38 rest against the buttons of the roof-shaped features 24 with their front ends 42 .

When a ferromagnetic actuator 44 is moved from the position shown in FIG. 2 to the position shown in FIG. 3, the slide plate 26 shifts to the left due to the magnetic forces of the permanent magnet 28 , whereby the slide plate assumes its left-hand end position. This position is shown in Fig. 3. In this switching position, the compression spring 32 is compressed and the left-hand contact fingers are lifted from the roof-shaped features, ie from the buttons on the contact tongues. At the same time, the opposing contact fingers put on the corresponding buttons, which cannot be seen from the representations according to FIGS. 2 and 3, since the cut surface runs through the center of the lead frame 36 and no contact fingers are provided on the side shown.

Once the ferromagnetic operating part 44 from the magnetic field of the magnet permant 28 is moved, the slide plate 26 shifts due to the bias of the compression spring 32 to the right in the corresponding Endlagenposi tion, which is shown in Fig. 2.

The left-hand contact fingers 38 come into contact again with the corresponding buttons of the roof-shaped features 24 .

Due to the inclined position of the buttons and the edging of the front ends 42 of the contact fingers 38 , there is contact of the buttons of the roof-shaped configuration 24 with the contact tongues 18 immediately before the end position, the contact fingers 38 being pushed slightly upwards, ie a slight contact friction occurs , which ensures safe contact.

For better switch activation, the ferromagnetic actuating part 44 can be designed as a magnet with the opposite polarity, which results in an amplification effect.

The electrical switch described above is very flexible with regard to the design of the switching functions, since the width of the frame 34 of the slide plate 26 and corresponding to the contact carrier 12 can be adapted to the desired number of contact options. In the illustration according to FIG. 1, lead frames with five contact tongues are provided, which, however, can be easily expanded to a correspondingly higher number of contact tongues by widening the lead frame. Accordingly, the frame 34 and the lead frame 36 are then to be made wider. Such widening does not have a disadvantageous effect, since it does not impair the sliding ability of the slide plate on the contact carrier and, on the other hand, there is no additional sliding friction between the two parts due to an increased number of contact fingers.

The electrical switch can be used very universally because it is made very small can and in different locks with ferromagnetic locking elements elements in its outer shape can be modified.

A preferred application of the electrical switch is for the buckle of an Si Safety belt provided in motor vehicles, the locking segment being a ferro is a magnetic part and acts as an actuating part for the electrical switch.

Claims (11)

1. Electrical switch for contactless switching with a ferromagnetic actuating part which actuates a contact against a restoring force by means of a permanent magnet, characterized in that
that in a housing ( 10 ) a contact carrier ( 12 ) with a plurality of electrical switching surfaces and with externally leading electrical connection contacts is fixedly mounted;
that a slide plate ( 26 ) on the contact carrier ( 12 ) is arranged displaceably and provided with contact fingers ( 38 ), the contact fingers ( 38 ) in the respective end position of the slide plate ( 26 ) alternately producing surfaces with a predetermined combination of switching surfaces ;
that with the slide plate ( 26 ) a permanent magnet ( 28 ) is firmly connected, the supply part in response to the positioned in its magnetic field ferromagnetic actuation part ( 44 ) of this is attracted and the slide plate ( 26 ) moves into a contact end position;
and that one between the slide plate ( 26 ) and the permanent magnet ( 28 ) arranged spring ( 32 ) with the elimination of the action of the ferromagnetic actuation supply part ( 44 ) moves the slide plate ( 26 ) back into its initial end position. 2. Electrical switch according to claim 1, characterized in that between the permanent magnet ( 28 ) and the slide plate ( 26 ) a Ausneh tion ( 30 ) is attached, in which the spring designed as a compression spring ( 32 ) between the slide plate's ( 26 ) on the one hand and a spring holder ( 16 ) projecting into the recess ( 30 ) on the contact carrier ( 12 ) is clamped on the other. 3. Electrical switch according to claim 1 or 2, characterized in that the buttons designed as contact tongues ( 18 ) are part of a punched grid integrated into the contact carrier, the individual contact tongues ( 18 ) being provided with roof-shaped features ( 24 ) whose mutually opposite oblique buttons, the contact fingers ( 38 ) provided in the slide plate ( 26 ) alternately come to rest in the respective end position of the slide plate. 4. Electrical switch according to one of claims 1 to 3, characterized in
that the contact fingers ( 38 ) are also part of a lead frame ( 36 ) integrated in the slide plate ( 26 ),
and that the front end ( 42 ) of the contact fingers ( 38 ) are edged in accordance with the obliquely running features ( 24 ) of the contact tongues. 5. Electrical switch according to claims 1 to 4, characterized in that the contact fingers ( 38 ) in the slide plate ( 26 ) are positioned such that they slide with the contact tongues ( 18 ) only shortly before reaching the two end position positions of the slide plate. come into contact. 6. Electrical switch according to claim 4, characterized in that the contact fingers ( 38 ) at the edged ends ( 42 ) are provided with stamped Ku gelkalotten. 7. Electrical switch according to one or more of claims 1 to 6, characterized in that the lead frame ( 36 ) with the contact tongues ( 18 ) is positively integrated in the contact carrier ( 12 ). 8. Electrical switch according to one or more of claims 1 to 7, characterized in that the lead frame ( 36 ) with the contact fingers ( 38 ) in an over the Kontaktzun conditions ( 18 ) open frame ( 34 ) of the slide plate ( 26 ) is injected . 9. Electrical switch according to one or more of claims 1 to 8, characterized in that the permanent magnet ( 28 ) in the front end of the slide plate ( 26 ) is embedded by injection molding. 10. Electrical switch according to one or more of claims 1 to 9, characterized in that the ferromagnetic actuating part ( 44 ) is formed as a magnet with the opposite polarity. 11. Electrical switch according to one or more of claims 1 to 10, characterized in that the electrical switch for querying the locking function of the locking segment of a mechanical belt buckle for motor vehicles is used, the locking element being a ferromagnetic part ( 44 ) and as an actuating part for serves the electrical switch.