DE1000528B - Set up on polarized electromagnetic relays with one-sided rest position - Google Patents

Description

The invention relates to polarized electromagnetic relays, particularly unilaterally stable Relay.

Most types of polarized relays are made of magnetic material with an armature and require a balance between that exerted by a spring on an armature in order to function mechanical force and the force caused by the polarized magnet system on the armature applied magnetic force. The mechanical force gives the armature a positive slope and tries to keep him in a neutral position between the two side contacts while the magnetic force creates a negative stiffness and tries to move the armature out of a position of unstable To pull equilibrium out against the next pole piece.

In the case of a mutually stable relay, the magnetic stiffness is greater than the mechanical, see above that the resulting stiffness is negative and consequently the anchor is from the position of the unstable Moved out of balance with increasing force until it is stopped by one of the side contacts.

In order to bring about the desired mode of operation of a relay that is stable on one side, it was usual to use the to put a side contact towards the middle position or beyond and the opposite Arrange the side contact so that the required contact gap is obtained. Then of course the anchor is prevented from centering and consequently traverses during movement of the armature from one contact to the other the piece of the armature in the working air gap of the relay only part of the air gap on one side of the center. Thus bed is a given air gap the available movement at the contacts is significantly restricted or reduced.

According to the invention, a one-sided stable, iron moving, polarized electromagnetic relay designed such that both the acting on the armature mechanical force as well as the magnetic force generated by the polarizing magnetic flux is caused at approximately the same position of the armature, which is from the center plane of the Relay air gap moved out or offset to her and outside the range of motion of the armature is to become zero. In a further development of the invention, it is proposed that the side compacts so set that the limit points of the movement of the armature equidistant from the Mitfcel plane of the air gap or the air gap come to rest.

The invention eliminates the aforementioned disadvantage, since the relay can work without the side contacts are polarized relative to the center plane of the relay device

electromagnetic relay

with one-sided rest position

Applicant: Telephone Manufacturing

Company Limited, London,

and Rupert Evan Howard Carpenter,

South Croydon, Surrey (UK)

Representative: Dipl.-Ing. E. Schubert, patent attorney,
Siegen (Westphalia), Oranienstr. 14th

Claimed priority:
Great Britain May 29, 1952

ao Frederick Emil Rommel, Ilford, Essex, and Rupert Evan Howard Carpenter, South Croydon, Surrey

(Great Britain),
have been named as inventors

have to be postponed or relocated; consequently the anchor can if one of any by the limits of its movement caused by the side contacts, over the entire length of the working air gap play away or move. The anchor is then on reaching the neutral equilibrium position (or in his striving to reach them) by meeting the side contact hindered at the end of its movement towards the neutral position.

There is no difficulty in the offset zero position of the mechanical acting on the armature Adjust the force, as this only requires the tensioning of a spring, usually the armature adjustment spring power. The offset zero position of the magnetic force acting on the armature can, however, on can be achieved in different ways, in practice among other things by the fact that the strength of the polarizing magnetic flux, which leaves the anchor or enters it, unequal on opposite sides is made large, or that the polarizing magnetic flux on opposite sides at differently spaced locations along the anchor is brought to action. The pole ends or tips of the polarized ones are advantageous Magnet arrangement designed asymmetrically on opposite sides of the armature.

The invention will now be explained in more detail with reference to the drawing, which shows it as an example be, namely shows or show

Fig. Ι a diagrammatic representation of the magnet system and the armature of the well-known Carpenter relay, as described in German patents 607 203 and 881 059 is described,

Fig. 2 is a force diagram which explains the operation of the relay shown in Fig. 1,

3 shows a similar force diagram for one according to the invention Relay,

4 is a similar explanatory diagram for modified conditions;

FIGS. 5 and 6 representations similar to FIG. 1 for embodiments according to the invention,

7 and 8 are partial views on opposite sides of a relay according to the German patent 872 063, which is designed eirfindungsgetnäß (the armature, the contacts and the magnet, which the observer facing but have been omitted), while

Figures 9 and 10 show, in similar diagrams as Figures 5 and 6, the application of the invention to two others illustrate known embodiments of iron moving polarized relays.

It can be seen that Fig. 1 is the counterpart to Fig. 5 of the drawing of German Patent 881 059, with the difference that the Seitenkon clocks c and c ' are set away to the right over the center line AB and that even the left contact c extends beyond this center line. Thus, when the signal winding is not energized, the tip of the armature a tries to move to the right of the neutral position, but it is stopped by contact with the side contact c ' , whereby the one-sided stable switching state is caused. The armature a is held or hinged between the permanent magnets m and in ' at p , and it can be easily seen that as a result of the adjustment of the side contacts c and c' the movement of the armature is limited and its lower end only a fraction of the gap between the magnet pieces I and / 'can cross.

In Fig. 2, the end faces of the legs / and V are represented by χ and y . The neutral or unstable position of the armature, which is in the middle here, is at point n. With the small movement quantities that come into question here, the mechanical forces and the magnetic forces are linear or directly proportional to the distances as a first approximation of the armature from the center n. Since the relay has its own lateral stability, the magnetic force shown by the full line Ma , ie the magnetic force that is proportional to the negative stiffness, is greater than the mechanical force Me shown by the dashed line Me and the ratio of the positive stiffness. The magnetic Force is greater, as shown by the greater slope of the line Ma .

The dash-dotted line R is the resultant of the forces Ma and Mc and is therefore directly proportional to the distance of the armature from the center n. If the coil w is not fed, the armature α (in FIG. 1) will move with increasing force 7? move clockwise as long as it is not prevented from doing so by contact c '.

For the purpose of explaining the invention, FIG. 3 shows a diagram similar to FIG. 2, which has the same reference symbols. In this case, however, it can be seen that the unstable or neutral point n, in which both the mechanical force Me and the magnetic! Force Ma become zero, is shifted to the left. It follows that the resulting force 7? when the relay is not energized, the armature α moves towards this point and that consequently the side contacts labeled c and c ' in FIGS. 2 and 3 can be arranged further apart and symmetrically to the central plane Cp of the relay. The distance between the points of the contacts c and c ' in FIG. 3 therefore embodies the useful air gap which, as can be seen, can be increased to a small value up to the full gap between the end faces χ and y . A comparison with FIG. 2 clearly shows the already mentioned fact that by moving the contacts c and c ' to the right to ensure stable operation on one side, the useful air gap drops below half the existing air gap.

The reason why the magnetic force Ma and the mechanical force Me are allowed to become zero at approximately the same point η is easy from the diagram according to FIG. 4, from which the main disadvantage can be seen particularly clearly, which is avoided by the invention , in which the lines Ma and Me cross the horizontal axis at different points ο and 0 ' . If z. B. the mechanical stiffness increases as a result of temperature changes, the slope of the line Me increases, as indicated by Me ' , while the slope of the resultant R becomes smaller, as indicated by 7?' indicated. As a result, the point at which the resultant line intersects the horizontal armature adjustment axis is shifted from η to n '. This means that the neutral position of the armature shifts along the horizontal axis, which results in a critical change in the values of the excitation current in the coil w at which the device is actuated and the armature is pulled against the side contact c ' and for those the anchor is released again. As can be seen in Figure 4, this can also result in a dangerous reduction in the reverse torque away from contact c when the excitation current is turned off. This reduction is indicated in the figure as reaching from / to F.

If n 'were moved beyond the position of the force of contact c , this force would be changed in its direction and the unilaterally stable effect would be completely lost.

In Fig. 5, an embodiment of a relay is shown in which the invention is applied to a magnet system as specified in German patents 607 203 and 881 059. In general, this relay results from that shown in FIG. 1, but with two fundamental differences. Firstly, the side contacts c and c 'are not shifted over the center plane AB , but are attached at equal distances on opposite sides of the center plane AB of the air gap between the legs / and /', and secondly, the system is unstable because the polarized permanent magnet m is arranged so that its end face is further away from the armature α at one end than the corresponding inner end face of the other magnet m '. In the example shown, this is achieved in that the permanent magnet m is made shorter than the magnet m ' . As a rule, the magnetic flux on the magnet leg V is greater than on the end face of the leg /, while the armature suspension spring j is set over or offset in such a way that when the relay is switched off, the armature α is stable on one side in the counterclockwise direction, as shown the contact c sets.

In Fig. 6, where the same reference numerals are used, the magnet system is brought out of equilibrium in that the pole faces of the permanent magnets m and w 'are placed at different points relative to the pin p and armature α . In this case, the armature control spring J is laterally offset so that the equilibrium position is deflected counterclockwise. When the relay is switched off, the armature rotates back clockwise and rests firmly on one side of the side contact c ' .

7 and 8 show the invention applied to a relay of the type described in German patent specification 872 063, the two permanent magnets tn and m ' overlap and the armature in the gap / wipe these magnets at right angles /.u them and swings here. 7 and 8 are partial views from opposite sides of the relay and correspond to FIG. 1 of the drawings of German patent specification 872 063, with the difference that in this illustration the armature 13 and the front magnet 9 are omitted, while some other parts not shown as stated in the earlier patent specification. It can thus be seen that the pole faces of the magnets m and m ' face the armature with respect to the armature pin at different heights; although the magnetic fluxes from the magnets w and m ' into the armature are of the same order of magnitude, in this case they act on different lever arms, whereby the magnetic imbalance state of the armature is achieved.

In Fig. 9 the application of the invention to another known form of relay is shown, the armature α is mounted at p near the upper ends of the magnets m and m '. As in Fig. 6, the dating magnets m and in ' turn their pole faces towards the armature a at different heights relative to the pin p , and the armature springs J are arranged in such a way that when the coil w is de-energized, the armature moves clockwise against the contact c'. is placed. The side contacts c and c ' are arranged centrally at equal distances on opposite sides of the center plane AB of the air gap between the magnet legs / and ΐ . With reference to the above explanations, the armature springs s are laterally offset in such a way that the mechanical force of the armature α becomes zero at the same point on the armature at which the magnetic force also becomes zero.

Finally, the invention in FIG. 10 is applied to a type of relay in which the armature α is stored in the center at p and surrounded by the excitation winding ze /, while the polarizing flux is generated by a horseshoe magnet m , so that the magnetic flux from the pole N and extends upwards and downwards, as indicated by the arrows χ , into the pole piece t , crossing the armature a at the tip and at the base, leads into the pole piece t ' and unites at the pole ^ ". Again, the side contacts c and c 'are centered and equally spaced on opposite sides relative to the center plane AB of the air gap. The magnetic force is offset in that the upper end r of the pole piece t opposite the end r' of the pole piece t ' and the The lower end r ^{2 of} the pole piece t can be displaced upwards relative to the lower end r ^{s of} the pole piece f and thus rotate the armature counterclockwise As before, the mechanical force is due to the pretensioning of the An kersteuerfeder i has been moved into the same neutral point.

Claims (5)

Patent claims: 1. Unilaterally stable, iron moving, polarized electromagnetic relay, thereby ao indicates that both the mechanical force acting on the armature and the magnetic Force caused by the polarizing magnetic flux at about same position of the armature, which is offset to the center plane of the relay air gap and outside of the armature's range of motion, become zero. 2. Device according to claim 1, characterized in that that the side contacts are set so that the limit positions are the same as the armature movement Have a distance from the center plane of the air gap or air gaps. 3. Device according to claim 1 or 2, characterized in that the offset zero position of the magnetic force acting on the armature is achieved by the strength of the polarizing magnetic flux, which leaves the armature or enters it, is of unequal size on opposite sides. 4. Device according to claim 1 or 2, characterized in that the offset zero position of the on the armature acting magnetic force is achieved that the polarizing magnetic flux on opposite sides at differently spaced locations along the anchor is brought to action. 5. Device according to claim 4, characterized in that that the pole ends or tips of the polarized magnet assembly are on opposite sides Sides of the anchor are designed asymmetrically. Considered publications:
German patent specification No. 734 040. 1 sheet of drawings