DE1250555B - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

HOIh

German class: 21g -4/01

Number: 1 250 555

File number: J 22390 VIII c / 21 g

Filing date: September 15, 1962

Opened on: September 21, 1967

The invention relates to an electromagnetic relay with protective tube armature contacts through Applying a correspondingly directed pulse to an excitation winding within the magnetic Circle to be brought to the attraction or to the fall and in which one within the magnetic circuit or several permanent magnets are arranged, which are short-circuited in the one working position of the relay and only act on the protective tube contacts with their leakage flux, while in the other working position of the relay, the short circuit is canceled, so that the magnetic flux of the permanent magnets acts fully on the protective tube contacts.

There are known electromagnetic relays with protective tube armature contacts, in which parallel to the Thermowell armature contacts a permanent magnet is arranged and one of the thermowell armature contacts and the field winding surrounding the permanent magnet together. These well-known Relays, which, depending on the magnetization status of the permanent magnet, are designated as idle or latching relays, but have the disadvantage that for the common surrounding the contacts and the permanent magnet Excitation winding a very large mean turn diameter is required and therefore for the Excitation winding itself a lot of copper is required. In addition, must be through a correspondingly high Pick-up pulse or ejector pulse, the entire force line field of the permanent magnet is compensated, to achieve the switching of the contacts. As a result, these well-known protective tube armature contact relays high tightening values are required. However, this in turn affects the installation size of the excitation coils off, so that this type of relay also takes up a lot of space.

Furthermore, it is already known to short-circuit the flux of the permanent magnet in its one position by means of a piece of soft iron in protective tube armature contacts that are actuated by a movable permanent magnet, so that only a small leakage flux can act on the contacts, while the short circuit in the other position of the permanent magnet is canceled so that the magnetic flux is fully effective. For example, German utility model 1 804 770 shows a pushbutton for actuating a protective tube armature contact which is excited by the magnetic field of a permanent magnet attached to the pushbutton by bringing it close to the contact when the button is pressed. In this push button, a piece of soft iron is provided to shorten the key stroke, which short-circuits the flux of the permanent magnet in the rest position of the key. The soft electromagnetic relay with
Protection tube anchor contacts

ίο

Applicant:

International Standard Electric Corporation,

New York, N.Y. (V. St. A.)

Representative:

Dipl.-Ing. H. Ciaessen, patent attorney,

Stuttgart 1, Rotebühlstr. 70

Named as inventor:
Edward Ronald Myatt, London

Claimed priority:

Great Britain September 21, 1961 (33 871)

iron piece but lies parallel to the longitudinally magnetized permanent magnet, so that it is on both sides of the permanent magnet's spreading force line field only short-circuits on one side, while the in Direction of the protective tube contact spreading force line field of the permanent magnet hardly from the Soft iron piece is affected. But since with this key version apart from the short circuit of the permanent magnet on one side of the permanent magnet at the same time by the resilient key shaft from If the protective tube contact is removed, the partial short-circuiting only occurs together with the removal of the permanent magnet opens the tongues of the protective tube contact. Such training is for one Relays not suitable, however.

Furthermore, in the German Auslegeschrift 1 071 767, a pulse switching device for generating Signal and call sign concerns, in which a rotating synchronous motor changes a magnetic field rhythmically, the influences a protective tube armature contact, the actuation of a protective tube armature contact with the aid of a Permanent magnets shown, with a permanent magnet associated control panel depending on their Position either allows the permanent magnetic flux to act fully on the armature contact or as a magnetic one The flux is shunted and the remaining leakage flux is insufficient to close the contact. After training this pulse switching device

709 648/265

There is a longitudinally magnetized parallel to the protective tube anchor contact arranged permanent magnet within a control panel made of magnetizable material, which is designed as a disc and opposite to each other in pairs at the edge on the front side Approaches. However, this arrangement has the disadvantage that the relatively short permanent magnet in every position of the control panel lies within the approaches of the control panel, so that there is always a large one Part of the flow closes back over the approaches and only a correspondingly smaller part between the approaches can pass through and run over the contact springs.

The invention is based on the problem of the disadvantages of an electromagnetic relay to avoid known arrangements. According to the invention this is achieved in that the magnetic Circle made up of one or two permanent magnets, a soft iron core and two movable anchors consists that the permanent magnet in its short-circuited position, the two movably mounted Anchor against the bias of tension springs with its magnetic field keeps attracted and that When the protection tube armature contacts are attracted, the magnetic flux of the permanent magnet flows through the through one in a certain direction applied to the excitation coil pulse generated magnetic flux supported will.

According to a further embodiment of the invention, the protective tube armature contacts are on both sides of the magnetic circuit arranged, and this is designed so that between two opposite Permanent magnets there is only one soft iron core on which for both magnetic pitch circles a common coil is arranged and in which the movable armature, which is angled in itself act on both magnetic pitch circles. By bending the two anchors, the two become magnetic pitch circles when operating the same differently influenced magnetically, so that the one magnetic pitch circuit is short-circuited, while in the other magnetic pitch circuit at the same time Time the short circuit is canceled. The two permanent magnets inside the two magnetic ones Part circles are arranged polarized in opposite directions, so that when the arrangement is actuated due to the differently effective magnetic flux that is arranged on one side Thermowell anchor contacts are closed, while the thermowell anchor contacts arranged on the other side be opened. At the two ends of a permanent magnet there are two loop-shaped ones Flux guide pieces attached so that they are within the relay arrangement in the direction of the protective tube armature contacts demonstrate.

The embodiment according to the invention has the advantages that relative to the known embodiments very small tightening values are required and that the permanent magnet is used to hold or attract the Protective tube armature contacts are no longer dependent on their magnetization strength. In this version you can use permanent magnets, which are fully magnetized, because they are then attached iron circuit magnetically short-circuited if the protection tube armature contacts are not tightened will. In addition, the arrangement according to FIG. 5 has the advantage that both Pages have a changing switching state, with the special within a circuit arrangement Effects can be achieved.

The invention is described with reference to a drawing. In the. Drawing shows
· F i g. 1 shows a schematic diagram of a relay according to the invention, the protective tube armature contacts of which are in the dropped position,

Fig. 2 shows the flow of flux within the magnetic circuit of the relay when a pulse is applied,

F i g. 3 the magnetic circuit of the relay in the position in which the protective tube armature contacts are kept closed,
F i g. 4 the course of the flux within the magnetic circuit of the relay when an ejector pulse is applied and

5 shows an arrangement in which two protective tube armature contacts located opposite one another in an alternating switching sequence operated by a magnetic circuit.

The relays that are described below are retentive or latching relays. A latching relay can be controlled by applying a work pulse, and this relay will held in its attracted position even after the end of the work pulse. Except the The excitation coil has a permanent magnet in this version of a latching relay, which connects the contacts of the Holding relay holds in attracted position. If the relay is not energized, the magnetic flux of deflected the contacts, but when the relay is energized, the excitation current changes the magnetic Lines of force so that the magnetic flux within the contact circle is significantly increased. Will However, if the excitation current is interrupted, the protective tube armature contacts will be, as already described held in their attracted position. Are the contacts inside the relay to open again are brought, it is necessary to apply another current or pulse to the excitation coil in order to be within of the magnetic field of lines of force to achieve a state in which the protective tube armature contacts fall off leaves or weakens the magnetic circuit so much that the protective tube armature contacts are not in held in their attracted position.

In Fig. 1, 1 denotes a protective tube armature contact to which a permanent magnet 2 is assigned, at the ends of which there are magnetic rings or loops 2a and 2b . This permanent magnet 2 is arranged outside the protective tube of the protective tube contact 1 and that at the level of the air gap of the two contact tongues. The permanent magnet 2 is further connected at its ends 2a and 2b with two armatures 5a and 5b, which are mounted at a pivot point 6a and 6b , with a soft iron core 4 to form a closed magnetic circuit. An excitation winding 3 is attached to the core 4. The free ends of the armatures Sa and Sb rest in the attracted position on the ends 2a and 2b of the permanent magnet 2. On the other side of the edition. surface is attached to each of the free ends of the armature Sa and 5 b a tension spring la and Ib , which pull the same from the ends 2a and 2b of the permanent magnet 2 when the armature Sa and Sb have fallen off.

Fig. 1 also shows the fallen state the protective tube armature contacts 1 within the relay. In this state the ends of the

Armature 5 α and 5 b held attracted by remanence from the ends la and 2b of the permanent magnet 2 and represent a closed magnetic circuit over the core 4. The flux generated by the permanent magnet 2 within this closed magnetic circuit is largely short-circuited in this, and the residual flux or the leakage flux of the permanent magnet 2 in the direction of the contact tongues of the protective tube contact 1 is no longer sufficient to attract them. The flux of the permanent magnet 2 is only able to keep the armatures 5a and 5b, as is also shown in FIG. 1, in the tightened state against the bias of the tension springs la and Tb. The dashed lines within the magnetic circuit of FIG. 1 and the arrows located on these show the course of the flux and the direction of flow within the magnetic circuit and also the course of the flux and the direction of the leakage flux of the permanent magnet 2 in the direction of the contact tongues of the protective tube contact 1.

As shown in FIG. 2, a pulse is applied to the excitation coil 3, which generates a magnetic flux within the magnetic circuit which is directed in the opposite direction to the magnetic flux generated by the permanent magnet 2, the remanence within the closed magnetic circuit according to FIG. 1 is canceled, and the armatures 5a and 5b are withdrawn from the ends 2a and 2b of the permanent magnet 2 under the pretension of the tension springs Ta and Ib. Since when the armature 5a and 5b are withdrawn at the free ends of the armature the same polarity is formed as that of the permanent magnet 2, the magnetic flux of the permanent magnet, which is no longer short-circuited by the magnetic circuit, is now concentrated only on the contact tongues within of the protective tube armature contact 1. This flow is supported in terms of direction by the flow generated by the pulse applied to the excitation coil within the contact tongues of the protective tube armature contact, so that this common flow, generated by the permanent magnet 2 and by the pulse applied to the excitation coil 3, is sufficient To close the protection tube armature contacts of the relay.

In Fig. 3 is the termination of the to the excitation coil 3 applied pulse shown in terms of state. The flux generated by the permanent magnet 2 is sufficient in this state to keep the protective tube armature contacts 2 in their closed position.

F i g. 4 shows the state of the relay, which is necessary to bring the protective tube armature contacts to waste again. In order to achieve this, a pulse with a current direction opposite to that in the example according to FIG this cancels within the contact tongues, so that the protective tube armature contacts are brought to waste. Within the permanent magnet 2, the flux generated by the excitation winding 3 has the same direction, so that the armatures 5 a and 5 b are attracted in the direction of the permanent magnet 2 from both sides. As a result, after the pulse applied to the excitation winding 3 has ended, the same switching position of the relay arises as has already been described according to the example in FIG. 1. The armatures 5a and 5b are kept attracted by the permanent magnet 2 even after the end of the pulse, so that the permanent magnet 2 is essentially short-circuited in terms of flux and the residual or leakage flux of the permanent magnet 2 in the direction of the contact tongues is insufficient to keep the open contact tongues to close again.

In the examples described so far according to FIG. 1 to 4, only one protective tube armature contact is drawn in each of the figures. In the practical embodiment of such a relay, however, two or more protective tube armature contacts 1 are arranged at the level of the permanent magnet 2 or its ends 2 a and 2 b , which open and close together in the sense described so far.

Fig. 5 shows an embodiment of a latching relay according to the invention, in which the protective tube armature contacts are arranged on both sides of a magnetic circuit doubled by two permanent magnets. The armature 5 a and 5 b are slightly angled in this case, so that when one side is short-circuited, the other side of the magnetic circuit is inevitably open. This results in the actuation of the protective tube armature contacts arranged on both sides that the contacts on one side are closed, while the contacts on the other side are open depending on the position of the armature or depending on the short-circuited or open part of the magnetic circuit, and vice versa. In this arrangement, the two permanent magnets are polarized in opposite directions within the magnetic circuit, so that a pulse applied to the common excitation winding inevitably causes the contacts to open on one side and to close the contacts on the other. The armatures are of course separated from each other and rotatably mounted, as previously described, with the one difference that according to the example, as shown in Fig. 5, an armature is used in each case, which has two free ends and through to both parts of the magnetic circuit its bending at the pivot point acts differently. The two anchor parts are supported on both sides of the core in the manner of a cutting anchor bearing.

Thermowell armature contact relays, as previously described, are particularly suitable for use in automatic Telephone systems suitable as crosspoint elements. Each cross point in a row of switches through which a connection can be established between the inner rows and the outer rows each have a single thermowell anchor contact for each connection. From these thermowell anchor contacts each contact can be controlled as shown in the examples in FIG. 1 to 4 described is.

Claims (5)

Patent claims: 1. Electromagnetic relay with protective tube armature contacts, which by applying a corresponding directed pulse to an excitation winding within the magnetic circuit for Attracted or brought to waste and in which within the magnetic circuit an or several permanent magnets are arranged, which are short-circuited in the one working position of the relay and only act on the protective tube contacts with their leakage flux, while in the other Working position of the relay, the short circuit is canceled, so that the magnetic flux of the Permanent magnet acts fully on the protective tube contacts, characterized in that the magnetic circuit consists of one or two permanent magnets (2), a soft iron core (4) and two movable armatures (5 a and 5 b) , that the S permanent magnet (2) is short-circuited Position holds the two movably mounted armatures (5a and Sb) against the bias of tension springs (z. B. Ta, Ib) with its magnetic field and that when the protective tube armature contacts (1 in F i g. 2) the magnetic flux of the Permanent magnet (2) is supported by the magnetic flux generated by a pulse applied to the excitation coil (3) in a certain direction. 2. Electromagnetic relay according to claim 1, characterized in that the protective tube armature contacts (1) on both sides of the magnetic circuit (2, 4, 5 a and 5 b) are arranged and this is designed so that between two opposing permanent magnets (2 ) there is only one soft iron core (4) on which a common coil (3) is arranged for both magnetic pitch circles, and that the movable armature (5a and 5b), which are angled in themselves, act on both magnetic pitch circles. 3. Electromagnetic relay according to claim 1 and 2, characterized in that by the angling of the two armatures (5 a and 5 b), the two magnetic pitch circles are magnetically influenced differently when operating the same, so that the one magnetic pitch circuit is short-circuited while in another magnetic pitch circuit at the same time the short-circuit is canceled. 4. Electromagnetic relay according to claim 1 to 3, characterized in that the two Permanent magnets (2) within the two magnetic pitch circles in opposite directions are arranged polarized, so that when the arrangement is actuated by the thereby different effective magnetic flux the protective tube armature contacts arranged on one side (1) closed, while the protective tube armature contacts (1) arranged on the other side are open will. 5. Electromagnetic relay according to claim 1 to 4, characterized in that at the two ends of a permanent magnet (2) two loop-shaped flux guide pieces (2 a and 2 b) are attached in such a way that they are within the relay arrangement in the direction of the protective tube armature contacts (1) demonstrate. Documents considered
German Auslegeschrift No. 1 071 767;
German patent specification No. 1 804 770. 1 sheet of drawings 709 648/265 9. 67 © Bundesdruckerei Berlin