DE835620C - Switch with several switch positions with electromagnetic opening and closing of the contacts - Google Patents

Description

Multi-position switch with electromagnetic opening and closing the contacts in the known switches for electrical current with multiple switch positions, the contact and thus the current circuit is direct or produced indirectly by one or more springs. If such a switch is switched on then either a spring slides on the contact track (s), or a stable conductor, which is moved further with the circuit, is led over contact buttons and pressed onto the contacts by a spring.

It is essential that the power connection is adhered to one another producing contacts is effected by spring pressure and that when further shading the spring pressure (contact pressure) remains unchanged.

In contrast to this, the invention aims to continue shading in the same level as usual, but breaking the circuit is supposed to take place in such a way that the movable contact is as perpendicular as possible from the stationary j or at an angle close to 90 ° by one or more electromagnets is lifted, which are controlled by the further shadowing.

As a switch in which the opening and closing of the contacts are electromagnetic happens, the well-known shooters can be considered. It does, however with these contactors no further switching, such as B. with a rotary switch, so that generally only two, at most three switch positions can be achieved. The idea of the invention, however, includes both electromagnetic contact for switches to continue shading with any number of switch positions on as well ensure that the direction of closing and opening of the contacts, as already mentioned, almost perpendicular, but at least at a significant angle to the direction of the switching takes place, in contrast to the normal contactor, in which the direction of switching and pressing of the contacts is identical.

If the switch according to the invention is in operation, pressure of the electromagnet directly or indirectly established the switching contact. The sink of the electromagnet can be actuated by any voltage. The interruption which is necessary for the electromagnet to fall off, can be done by the grid itself take place or be coupled with the grid or by one when switching on of the switch on a special disk or shaft arranged device for Interruption of contact of the supply current; z. B. Cam disc, to the coil (s) of the electromagnet (s).

With this facility, when switching to a low Moving the switch further in the switching direction, e.g. B. by rotation, the power interruption brought about to the coil. The electromagnet drops out, opening the circuit. As soon as the switch is moved so far that the electromagnet over the next Contact is made, the interruption of the current to the coil is canceled, the electromagnet picks up, establishes the connection to the next switching contact and thus closes the current to be switched.

The particular advantage lies in the fact that with relative high specific contact pressure can be worked because the actual further movement the next contact occurs almost exclusively after the contact pressure has been released. If you wanted the same effect with mechanical lift-off when using spring contact pressure reach, the spring would first give way and only then would it be lifted off In any case, it would not fall as quickly as an electromagnet would expected.

Another advantage is that "the arc when lifted vertically the contact is not dragged from one contact to the other. On the contrary it will With this type of switching, the contact opening takes place perpendicular to the level of switching, and so you can adjust the arc path by choosing the electromagnet accordingly take very large even when the switch contacts are close together and still, if one chooses the electromagnet accordingly strong; Achieve contact prints, which are difficult to produce with springs.

Fig. I shows an embodiment of the switch according to the invention, in which by an electromagnet the contact both to the contact button as well is produced at the same time on the power take-off rail. The axis i is with the Handle 2 is rotatably held in a bearing in the non-conductive base plate 3. on the axis i is an arm 4 fixedly mounted, the electromagnet at its end 5 carries, the coil 6 is drawn semi-schematically and its iron core 7 over an isolated intermediate piece the contact bridge 8 once on the power supply rail j and on the other hand, depending on the position of the switch, on any number of contact buttons io, 11, 12, 13, 14, 15, 16 and 17 can press on when power is supplied to the coil 6. The electromagnet is counteracted by a spring (not shown here), which when it is de-energized Coil lifts the electromagnet from the contacts and thus interrupts the current. The power supply to the coil 6 takes place once via the line 18, which has a small Sliding contact i9, which is attached to the base plate 3, the current to the itself with the axis rotating current pickup ring 20 leads, from which he via the line 21 reaches a pole of the coil. The second power supply to the coil is via the line 23 to a resilient contact 24, which is also attached to the base plate 3 and that the current through the contact ring 25 and the Leiturig 27 to the second pole the coil leads. The spring contact 24, however, only touches the current pick-up ring 25 when he in a notch of the notched made of insulation material Ring 26 is, which is also firmly connected to the axis and with this turns.

If you switch the switch further by turning button 2, then the contact spring 24 lifted out of the notches of the ring 26, the power supply interrupted between contact 24 and ring 25 and thus the coil 6 is de-energized. the Not shown, the electromagnet counteracting spring then pulls the electromagnet from the contacts. As soon as the contact spring 24, when the switch is turned, reaches the next notch of the ring 26, the circuit is again via 24-25 the coil is closed and the electromagnet 5 attracts. Because the notches are so arranged are that they then each allow the contact 24-25 when the contact bridge 8 has just arrived via the individual contacts io to 17, the contact will be each closed in this switching position. Practically done this way the opening and closing of the contacts almost perpendicular to the switching level.

Another embodiment is shown in Fig. 2. Here, too, is the axis i rotatable on the insulated handle 2 in a bearing of the fixed insulated base plate 3. The arm 4, on which the coil 6 with the iron core is attached, is firmly connected to the axle 5 is mounted. If the electromagnet receives 5-6 current, the iron core 5 presses the in a hinge mounted on the arm 4 io rotatable lever 9 and thus the Contact pins 7 and 8 connected by a wire bridge once on the contact buttons 14 to 21 etc. and on the other hand on the busbar 13. When the coil 6 is de-energized spring ii opens contacts 7-14 to 21 and 8-13 by lifting the lever 9 against the working direction of the electromagnet. The coil gets its current once via the line 23, which is attached to the resilient on the base plate 3 Contact 24 leads, which presses on the disc 25, from which the current to a The end of the coil 6 arrives. When switching on, this power supply is interrupted therefor the disc made of insulation material and provided with notches 26 lifts the contact 24 from the slip ring 25 until another notch is in front the spring 24 arrives. The notches are arranged that they each make contact 24-25; if the arm 4 and 9 exactly over the individual switch contacts stand. The second .Pol of the coil 6 receives current via the line 27 with the sliding contact 28, from where it arrives at the slip ring 29, from which it is guided to the coil 6.

Fig. 3 shows in section a further embodiment of the invention Switch. The axis i with the non-conductive handle 2 rotates in a bearing in the solid, non-conductive base plate 3. The is permanently mounted on axis i Arm 4, which carries a contact bridge 5 attached in an insulated manner. The axis i consists made of non-ferrous and non-nickel metal. An iron core 6 is inserted into it, which at the same time acts as the core of the electromagnet. The coil 7 of the electromagnet 6-7 is fixedly mounted on a non-conductive plate 8, which is displaceable on the axis i is appropriate. This plate 8 carries the contact buttons, of which here in section four, namely 9, 10, 11, 12 are drawn. They go easily from the contact buttons moving lines to the fixed base plate 3. When the electromagnet is attracted the plate 8 with the contact buttons rises and presses them against the bridge 5. The coil 7 receives on the one hand power directly from the line 18, on the other hand via the Line 13 with the resilient sliding contact 14; which is firmly mounted on the base plate 3 and presses against slip ring 15. From this slip ring 15, the leads Line 16 to coil 7. Contact 14-15 can only be established if the resilient contact 14 in a notch made of insulating material and with Notched disc 17 engages. This disk 17 is fixed to the axis tied together. When switching on the handle 2, by rotating the disk 17, the resilient Contact 14 pushed out of the notch. He then does not touch the slip ring 15 more, and the coil 7 is de-energized. Only when reaching into the next notch of the Disc 17 and the resulting contact closure 15-14 are given to the coil 7 again Current. The notches are now each attached in such a way that the current only then returns can flow when the bridge 5 is over the next contact button. is the current is interrupted, the contact is released, the plate 8 is not shown by Springs, which counteract the electromagnet, are pushed back into their previous position.

Another variation of the switch according to the invention is shown in Fig.4. Here, too, an axis i made of non-ferrous and non-nickel metal is included a handle 2 made of insulating material in a bearing of the non-conductive Bottom plate 3 rotated. On this base plate 3 there are four contacts 4 on average, 5, 6 and 7 visible, of which 4 and 5 and 6 and 7 through conductive bridge pieces 8 and 9 are connected when the rail 1o, which carries these bridges, on the Contacts 4, 5, 6, 7 are pressed on when the electromagnet is attracted. The coil ii of the electromagnet is firmly connected to the rail io, and the iron core 12 is permanently incorporated into axis i. A driver 13 leaves the rail io follow the rotation, but on the other hand allows a movement in the axial direction, see above The bridges 8 and 9 are pressed onto the contacts 4, 5, 6, 7 and also from these can be withdrawn. The coil ii of the electromagnet 11-i2 receives power once via line 14, in this case (as an example) that of the electromagnet counteracting spring is used as a mediator. The break in contact with the Coil takes place exactly or similarly as in Fig. I, 2 and 3 via spring contact and via a notched disc or in any other known manner when rotating of the switch. Reference can be made to the previous descriptions.

Fig. 5 shows a series of possible arrangements in a rough schematic manner of the electromagnet. The electromagnets are each designated as EM. The small Arrows show the pulling direction of the springs counteracting the electromagnet, which are not shown. In Figs. 5 e, 5 f, 5 h, 5 i, 5 k are the electromagnets Drawn in a suit, i.e. the power contacts are closed. In Figs. 5 a, 5 b, 5 c, 5 d, 5 g they are open. In Fig. 5 f only one contact is shown, the power supply is only indicated and can be done via sliding contact or any other type. These examples are also selected from a multitude of possibilities.

Claims (3)

PATENT CLAIMS: i. Switch with several switching positions, characterized in that the closing and opening of the contacts is carried out by electromagnets and that the contacts open at the beginning of switching by the dropping of the electromagnet (s) and the connection to the next switching contact by the The electromagnet is only attracted as soon as the switch is above this contact, regardless of whether this effect is achieved by one or more electromagnets in the movable or fixed part of the switch directly or indirectly via lever transmission or similar .. 2. Switch according to claim i, wherein the rotatable or during switching moved parts of the switch always be kept in the same plane while the contacts themselves by the effect the electromagnet in the event of a current connection against the corresponding devices of the rotatable or moving parts are pressed when switching. 3. Switch according to claim i, at where the electromagnet (s) are centrally located and either the contact bridge (s) in the rotatable (moving) part when the electromagnet (s) are attracted to the fixed contacts or these contacts on the assigned contacts or Contact bridge (s) in rotatable (movable) part pressing.