DE2128557C - Polarized relay - Google Patents

Description

The invention relates to a polarized relay with at least one contact set and with one magnetic circuit to which a permanent magnet with a first and second pole piece, one on one Side of the first pole piece attached and wound with a coil core, a contact set actuating Anchor with two arms, of which the first arm has a first air gap and the core the second arm forms at least one second air gap with at least one of the pole pieces, and a with the second pole piece connected yoke, which forms a pivot point for the armature, to the anchor in a first stable end position, in which the first air gap is smallest and the second air gap is largest, and in a second stable end position in which the first air gap is on largest and the second air gap smallest; is, is pivotable, wherein the magnetic flux of the permanent magnet holds the armature in one of the two stable end positions and an excitation current opposite polarity in the excitation coil the armature with the contact set in the respective opposite The end position can tilt.

Such polarized relays are known and are also referred to as hold or surge relays. The permanent magnet pulls the relay armature into one of two stable end positions, and to switch the armature, the coil is excited by a directed excitation current so that a dem permanent magnetic flux opposing magnetic flux is generated, which lifts the armature and into its toggles opposite stable end position.

The well-known relay described above has the

ίο Disadvantage that the magnetic flux of its permanent magnet, which holds the anchor in the rest position, not a suitable closed iron path vorf-.idet. The consequence is that the permanent holding force in the event of vibrations, shock loads, etc., it is not sufficient to place the armature in the To hold the end position securely. This can lead to uncontrolled contact activities. At least In one end position of this relay, the permanent holding force acts through the contact pressure of the

the armature operated contact spring sets against. It shines as a permanent one that is limited in any case Holding force is only sufficient to overcome relatively weak contact spring sets; so you can do not use any strong contacts and accordingly do not switch any high currents.

The invention is based on the object of improving a relay of the type mentioned so that you duss it its rest positions auv.li under vibration and shock loads 1 and one for

all contact spring sets that occur develop sufficient permanent holding force.

According to the invention, this task is solved that the second arm with the first pole piece in forms the second air gap in a manner known per se; and that the anchor has a third arm that is connected to the second pole piece forms a third air gap, which is smallest in the first stable anchor end position and is greatest in the second stable end position.

This enables d;> ß in the first stable end position two parallel permanent magnetic fluxes are formed, of which the first over the first arm and gap to the core, and the second magnetic flux via the third arm and gap to the second pole piece runs; these two parallel magnetic fluxes keep the armature in its first staoilen end position firmly. This achieves a high level of shock and vibration resistance that has not yet been achieved, and stronger contact spring sets can also be used.

It is preferably provided that the second arm also cooperates with the second pole piece and there forms a fourth air gap, which is greatest in the first stable end position υ · - in the second stable end position is smallest, so that in the second stable end position of the second arm two pole shoes directly bridged.

In this way, a similarly large permanent holding force is also achieved in the second stable end position, because the permanent magnetic flux is now directly short-circuited via the second arm.

Further details and advantages of the invention can be found in the following description of a preferred Embodiment can be taken with reference to a drawing. It shows

F i g. 1 is a schematic representation of a polarized relay according to the invention in a stable one End position and with indicated flux of lines of force and

Fig. 2 shows the same relay as in Fig. 1, but in part via the yoke 18 with the pivot point in

the opposite stable end position. the arm 10, from there into the arm 12 and over the

The air gap 30 selected and shown schematically in the drawing passes back into the core 26 while

illustrated embodiment of a Halierelais the other part of the magnetic flux via air gap 36,

has an anchor with four arms 10, 12, 14 and 16 5 arm 16, arm 12 and air gap 30 also back

on. The armature is guided into the core 26 via the arm 10 on a yoke. During the

18, because the armature has a high reluctance with the magnetic flux of a manentniagnet 22

Pole piece 20 of a permanent magnet 22 connects the magnetic flux generated by the excitation current

rotatably mounted. A second pole piece 24 of the person still another way, although an even higher one

Manentmagneten 22 has a core 26 with an io reluctance, but the following is not to be neglected:

Excitation coil 28 connected. The free end of this path leads from the core 26 through the pole piece

Arm 12 is located near the free end 24 and from there over the armature in this position

of the core 26 and there forms an air gap 30. The large air gap 34 to the remote arm 14 and from

Arm 14 lies over both the pole shoe 20 and the arm 12 and the narrow air gap 30, forming there

an air gap 32 as well as the pole piece 24 under 15 back to the core 26. Naturally, the in the

Formation of an air gap 34 opposite, during the armature position according to FIG. 1 large air gap 34 too

Arm 16 on the opposite side of the pole- a high reluctance which i '- <yoke becomes smaller, below

shoe 20 forms an air gap 36. In the increase in the flow of metal shown in Fig. 1, its and the anchor in the

The end position of the armature shown is the air gap opposite end position according to FIG. 2 drawn

30 and 36 smallest, while the air gap 32 becomes 20. As the drawing shows, the from

and 34 have their size value. In the in Fi g. 2 Excitation current generated magnetic flux to a large extent

shown opposite end position of the armature the same way as the magnetic flux of the permanent

However, the dimensions of the individual air magnets 22 behave in opposite directions everywhere

column exactly the other way around. Mechanically linked to the direction of flow. As a result, the result is

The armature is a set of changeover contacts 38, causing a residual magnetic force of attraction between

consisting of a movable contact 38/4 and opposing surfaces within the air gap

two opposite fixed contacts 383 and 30 and 36 small, when the excitation current flows, while

38C. rend a greater magnetic attraction between

The contact set 38 is in the direction of the see in both sides of the air gap 34 prevails ¹ , so

F i g. 2 end position shown resiliently preloaded, where the 30 that the armature is switched, especially since the l'ni-

movable contact 38Λ with the fixed contact 38 B switching movement still through the spring preload

connected is. Therefore, it is sufficient to be able to move mechanically. Contact 38/1 is supported

bond between the armature and the contact set, however, if no excitation current flows, the armature will

38 an actuating pin 39, which is moved by the magnetic flux of the permanent magnet 22

Contact 38/1 in the end position of the armature according to 35 across the air gaps 30 and 36, safely in

Fig. 1 presses against the fixed contact 38C, held during its end position according to FIG. 1, namely

it in the opposite end position of the armature also against the bias of the contact

(see Fig. 2) simply releases, so that he can go to the feast 38.
koniakt 38ß can return. If the anchor is in its end position according to

In Fig. 1 and 2 is the magnetic flux of the permanent 40 Fig. 2, the magnetic flux of the permanent magnet flows " 22 in broken lines and the magnet from the pole piece 24 across the air gap 34 in Magnetic flux of the excitation coil 28 in continuous the arm 14 and from there in the short circuit over the or dash-dotted lines. Pole shoe 20 back into permanent magnet 22.

In the end position of the armature Da shown in FIG. 1, the reluctance in the air gaps 32 and 34 If the magnetic flux of the permanent magnet 22 45 is low, most of the magnetic flux becomes from the pole piece 24 through the core 26, skips that shorted by the arm 14, but a smaller one Air gap 30, which in this armature position very part flows from the air gap 34 via the arm 14 is kleir and thus has a low reluctance, and the arm 10 to the armature pivot point unci from there and finally arrives in the arm 112, where it returns to the pole piece 20 via the yoke 18. Want Magnetic flux divides. A portion flows over the arm 10 and 50 and the anchor is now in its opposite ends Armature pivot point in the yoke 18 in the pole shoe position according to FIG. 1 switch back, so you need 20 back, while the other part of the magnet - an excitation current of opposite polarity, fluxes over the arm 16 of the armature and in this the magnetic flux generated by this excitation current Position likewise small air gap 36 in the pole comes from the core 26 via the air gap 30, the shoe 20 and thus in the permanent magnets 22 55 now has a low reluctance, in the arm 12. flows back. In addition, of course, there is a certain amount of Here the magnetic flux divides, and a part arrives There is a leakage flux that is looking for other ways. via the arm 10, the anchor pivot point and the yoke the reluctance of which, however, is much greater, so that 18 in the pole piece 20 crosses the air gap 32 the leakage flux can normally be neglected and gets into the arm 14 while the other part can. If in the anchor end position according to FIG. 1, which 60 arrives in the arm 14 by the direct route, from Frrcgerspult?, 8 with a current corresponding to where the now reunited magnetic flux the air polarity energized, it generates a magnet gap 34 crossed and via the pole piece 24 into the Liuß of the permanent magnet 22 against the oppositely directed core 26 has come back. You can see that the magnetic flux Via the air gaps 30 and 36, and the flow of the permanent magnet 22, the magnetic flux of the The armature of the relay switches over. This excitation 65 excitation current within the arm 14 and the current originating magnetic flux comes from the air gaps 32 and 34 is opposite, so uaß Core 26 via the pole piece 24 and the permanent magnet when the excitation current is flowing 22 into the pole piece 20, where it divides, and drawing between the opposing surfaces

the air gap 32 and 34 is small while there is a greater attraction on either side of the air gap 30 prevails, which switches the anchor. If there is no excitation current, the magnetic flux of the is sufficient Permanent magnets 22 completely off to by the attraction force generated within the air gaps 32 and 34 the anchor firmly in its end position according to FIG. 2 hold. In general it can be said that the magnetic flux from the permanent magnet 22 in the absence of a high current also under external Influences such as mechanical shock loads or vibrations are sufficient in any case, the anchor in one to hold its two stable end positions securely. It should also be said that the representation of the chosen Embodiment of a polarized relay according to the invention in the drawing is schematic and leaves the design to be selected in practice completely open. For example, the Arms 14 and 16 can be designed as separate components; but they can also (as shown) common Own elements. The excitation coil 28 can consist of more than one winding, and the contact set 38 can consist of consist of several sets of contacts. In a preferred Ausrührungsbeispiel the invention butt opposite surfaces of the Luftspaltc 30, 32, 34 and 36 together when these airgaps in the corresponding anchor end position have their minimum value.

However, there is absolutely no need for the opposing surfaces of each Air gaps collide as long as only the smallest value of the air gap is significantly smaller than the Greatest value is. The point at which the arm 16 is attached to the arm 14 can to some extent be free to get voted; in special cases it can be attached close to the free end of the arm 14.

1 sheet of drawings

Claims (2)

Patent claims: 1. Relay with at least one contact set and with a magnetic circuit, to which a permanent magnet with a first and second pole piece, a core attached to one side of the first pole piece and wound with a coil, an armature actuating the contact set with two axes, of which the first arm with the core forms a first air gap and the second arm with at least one of the pole pieces forms at least a second air gap, and a yoke connected to the second pole piece belongs, which forms a pivot point for the armature around which the armature is in a first stable End position in which the first air gap is the smallest and the second air gap is the largest. and is pivotable into a second stable tiid position, in which the first air gap is the largest and the second air gap the smallest, the magnetic flux of the permanent magnet holding the armature in one of the two stable end positions and an excitation current of opposite polarity in the excitation coil holding the armature tilting the contact set into the respective opposite end position, characterized in that the second arm (14) forms the second air gap (34) with the first pole piece (24) in a manner known per se; and that the armature has a third arm (16) b a third air gap (36) with the zweiven pole piece ⁽²⁰⁾ which is .ldet in the first stable anchor end location on the smallest and in the second stable end position at its greatest. 2. Relay according to claim 1, characterized in that the second arm (14) also with cooperates with the second pole piece (20) and there forms a fourth air gap (32) which is largest in the first stable end position and smallest in the second stable end position, see above that in the second stable end position the second arm bridges the two pole shoes (20, 24) directly.