EP1626427A2 - Relay - Google Patents

Abstract

The electromechanical relay has wound coil [14] mounted on a yoke [20] with an armature [30] located in a pivoted position [26]. The armature is subjected to a spring return [40] force. Mounted on the armature is a leaf spring [50] carrier that has a contact [70] at the tip. When the coil is energised the contacts close.

Description

The invention relates to a relay comprising a base, an electromagnet arranged on the base, an armature with at least one pivotally mounted on the base and movable by means of the electromagnet between a contact-releasing end position and a contact end position armature, a movable means of a first Einwirkungsmöglichkeit part of the armature Contact spring, which extends with at least one spring arm up to at least one actuation region, at least one first contact element, which acts on the contact spring by means of the at least one actuation region, and at least one arranged on the base second contact element, on which the first contact element in the contact-making position the anchor arm can be applied by means of a contact force generated by deformation of the contact spring.

Such relays are known in the art.

In these, there is always the demand for the greatest possible contact force.

The invention is therefore based on the object to obtain the largest possible contact forces with the lowest possible power during energization of the electromagnet.

This object is achieved according to the invention in a relay of the type described above in that the armature arm has a support region facing the spring arm for acting on a region of action of the spring arm, that the spring arm extends in the contact-releasing position of the anchor arm with the action area at a distance from the support area and that at least in a contact-making end position of the anchor arm of the anchor arm by acting on the support region on the action region of the spring arm has a further possibility of action on the contact spring, which acts in the sense of amplifying the contact force generated by the contact spring.

The advantage of the solution according to the invention is thus to be seen in the fact that it is possible by simple means to generate the greatest possible contact force, that the support area acts in addition to the first action possibility with the second action possibility on the spring arm, preferably with delay.

This reinforcement of the spring force by the additional action of the armature arm with the support area on the impact area has the advantage that the resulting higher contact force from the armature must be absorbed only when the anchor arm is already relatively far from the contact-releasing position in the direction of its contact-making end position has moved.

It should be noted that the counteracted by the anchor and the contact force corresponding counterforce depends on how large the air gap between the armature and the armature attracting pole face of the Electromagnet is. The smaller this air gap, the greater counter-forces can absorb the anchor without its movement is disturbed to reach the contact-making end position of the respective anchor arm or hindered by the opposing force.

It is particularly favorable if the support region is arranged on the armature arm in such a way that the area of action of the spring arm can be acted upon after a first contact of the contact elements and before reaching the contact-making end position of the armature.

Characterized in that at a first contact of the contact elements, the contact force and thus absorbed by the anchor counterforce is small and the contact between the support area and the impact area only after a further deformation of the spring arm, the resulting larger contact forces and thus larger opposing forces occur only then, if between the armature and this attracting pole face of the electromagnet, a very small air gap still exists and thus the attraction of the electromagnet is already so large that it can accommodate the larger contact force corresponding counterforce.

This ensures that the effect of the support region and thus the occurrence of a larger contact force, which leads to a greater drag on the armature, only at a relatively small air gap between the armature and the electromagnet use.

The effect of the support area on the impact area was not defined in more detail in connection with the exemplary embodiments described so far. Thus, it is particularly favorable if the support region has at least one support point with which the support region acts on an action point of the action region on the spring arm.

With this simplest embodiment of the further possibility of influencing the spring arm, the contact force can be increased in a structurally particularly simple manner.

In principle, the additional support of the spring arm in the area of the action point could still allow complex resilient movements of the spring arm.

However, a particularly favorable solution provides that cooperate at the support point and the point of action of the anchor arm and the spring arm such that a spring action of the spring arm is limited to a lying between the point of action and the actuating portion of the spring arm. This can be increased in a simple manner caused by the spring action contact force.

In the foregoing, only one support point and one resulting point of action were assumed.

The concept according to the invention for increasing the contact force can be realized in a particularly favorable manner when the support region has a plurality of support points which act on a plurality of action points, thereby providing a multiplicity of further action possibilities with which the contact force can be adapted to the force relationships at the armature.

It is particularly advantageous if, during a movement of the armature arm from the contact-releasing end position into the contact-making end position, the plurality of support points act successively on the corresponding action points.

In several, consecutively acting on impact points support points they are arranged so that the successively cooperating support points and action points cause an ever-increasing contact force.

This can be realized structurally simple in that the successively cooperating support points and action points are arranged at an increasingly smaller distance from the actuation area.

Conveniently, the support points act on the corresponding points of action only after contact with the contact elements, so that the opposing forces generated by the increased contact forces on the armature does not hinder the movement of the armature in the contact end position, since in these positions from the electromagnet to the armature acting forces are sufficiently large.

In the context of the solution according to the invention, the supporting points and action points can be formed as successive surface areas, which complement each other to an ever-increasing interaction surface.

A structurally easily realizable embodiment provides that the support area or the impact area are step-shaped and form step edges thereof the support points or points of action.

In principle, the support region and the action region could cooperate in such a way that they have an extension in the direction parallel to the joint axis, which improve a tilting stability of the actuation region.

However, it is particularly favorable, in particular when the contact elements are arranged on bridge contacts, when the support area and the action area are designed to permit movement of the spring arm about a tilt axis extending transversely to the hinge axis of the armature.

Preferably, this can be realized in that the support area and the action area in the direction of the tilt axis cooperate maximally substantially linear.

It is even more advantageous if the supporting area and the area of action cooperate in a substantially point-like manner, since in this case the spring arm has the possibility of optimally adapting to the reaction forces arising when the contact elements abut one another.

In particular, in the case of contact bridges with two spaced-apart first contact elements, provision is preferably made for the support region and the action region to have an extension in the direction parallel to the joint axis which is smaller than one quarter of a distance of the first contact elements in the direction of the joint axis.

With regard to the arrangement of the contact spring relative to the anchor so far no further details have been made.

In principle, it would be conceivable to arrange the contact spring on a side facing away from the second contact element of the at least one anchor arm. In this case, however, the realization of the support area and the action area is complicated because they would have to cooperate in such a way that the spring element is acted upon in the direction of increasing the contact force.

For example, in this case, either the spring arm or armature arm or both elements would be provided which engage behind the anchor arm or the spring arm or each other and bear against the spring arm, armature arm or against each other during the interaction of the support area and the action area.

However, the solution according to the invention can be realized in a structurally particularly simple manner if the spring arm of the contact spring is arranged on a side of the armature arm facing the respective second contact element. In this case, the support region and the exposure region can be arranged and formed in a suitable manner on the side of the anchor arm facing the spring arm and the arm side facing the armature arm.

With regard to the relative position of the electromagnet and the contact spring to each other so far no further details have been made. Thus, an advantageous solution that the contact spring is disposed on a side facing the electromagnet of the armature.

In this case, the contact spring is to be arranged so that it extends outside of a Polanlagefläche the armature.

Alternatively, it is preferably provided that the contact spring in the region of the Polanlagefläche has a recess, so that the formation of the contact spring and the positioning of the Polanlagefläche at the anchor are independent of each other.

Another advantageous solution provides that the contact spring is disposed on a side opposite the electromagnet side of the armature.

In this case, it is expedient if a contact surface of the armature abutting the electromagnet in the contacting end position is arranged on a side of a joint opposite the contact elements for the pivotable mounting of the armature.

A particularly favorable solution provides to form the electromagnet as two magnetic poles having magnets, each of which cooperates with an anchor arm of a rocker designed as a rocker.

In order to prevent the contact elements from hitting each other when moving the armature from the contact-making end position into the contact-releasing end position, it is preferably provided that the actuation area is coupled to the armature via a retaining element which in particular permits such a relative movement of the spring arm relative to the armature arm. that the support area and the action area abut each other or can be at a distance from each other.

In the simplest case, such a holding element is designed as a movement of the spring arm relative to the anchor permitting stop element.

Further features and advantages of the invention are the subject of the following description and the drawings of some embodiments.

Fig. 1

eine Seitenansicht eines ersten Ausführungsbeispiels eines erfindungsgemäßen Relais in einer kontaktfreigebenden Endstellung des Ankers;

Fig. 2

eine Seitenansicht entsprechend Fig. 1 in einer kontaktgebenden Stellung des Ankers;

Fig. 3

eine Draufsicht auf eine Einheit aus Kontaktfeder und Anker in Richtung des Pfeils A in Fig. 1;

Fig. 4

eine Ansicht der Einheit aus Kontaktfeder und Anker in Richtung des Pfeils B in Fig. 3;

Fig. 5

eine Darstellung ähnlich Fig. 1 eines zweiten Ausführungsbeispiels eines erfindungsgemäßen Relais;

Fig. 6

eine Darstellung ähnlich Fig. 2 des zweiten Ausführungsbeispiels des erfindungsgemäßen Relais;

Fig. 7

eine Draufsicht auf den Anker beim zweiten Ausführungsbeispiel in Richtung des Pfeils C in Fig. 5 ohne Kontaktfeder;

Fig. 8

eine Seitenansicht des Ankers in Richtung des Pfeils D in Fig. 7;

Fig. 9

eine Ansicht des Ankers in Richtung des Pfeils E in Fig. 7;

Fig. 10

eine Darstellung ähnlich Fig. 3 des Ankers mit Kontaktfeder beim zweiten Ausführungsbeispiel des erfindungsgemäßen Relais;

Fig. 11

eine Darstellung ähnlich Fig. 4 beim zweiten Ausführungsbeispiel des erfindungsgemäßen Relais;

Fig. 12

eine Ansicht in Richtung des Pfeils F in Fig. 6 beim zweiten Ausführungsbeispiel des erfindungsgemäßen Relais;

Fig. 13

eine Ansicht ähnlich Fig. 1 eines dritten Ausführungsbeispiels eines erfindungsgemäßen Relais;

Fig. 14

eine vergrößerte Darstellung eines Abstützbereichs und eines Einwirkungsbereichs beim dritten Ausführungsbeispiel entsprechend Fig. 13;

Fig. 15

eine Ansicht in Richtung des Pfeils G in Fig. 13;

Fig. 16

eine Darstellung ähnlich Fig. 2 des dritten Ausführungsbeispiels des erfindungsgemäßen Relais;

Fig. 17

eine vergrößerte Darstellung des Abstützbereichs und des Einwirkungsbereichs beim dritten Ausführungsbeispiel gemäß Fig. 16;

Fig. 18

eine Draufsicht in Richtung des Pfeils H auf den Anker des dritten Ausführungsbeispiels gemäß Fig. 16;

Fig. 19

einen Schnitt längs Linie 19-19 in Fig. 13;

Fig. 20

eine Ansicht entsprechend Fig. 15 mit Darstellung einer Kippbewegung des Ankers und

Fig. 21

eine Darstellung ähnlich Fig. 16 bei einem vierten Ausführungsbeispiel eines erfindungsgemäßen Relais.

In the drawing show:

Fig. 1

a side view of a first embodiment of a relay according to the invention in a contact-releasing end position of the armature;

Fig. 2

a side view corresponding to Figure 1 in a contact-making position of the armature.

Fig. 3

a plan view of a unit of contact spring and armature in the direction of the arrow A in Fig. 1;

Fig. 4

a view of the unit of contact spring and armature in the direction of arrow B in Fig. 3;

Fig. 5

a representation similar to Figure 1 of a second embodiment of a relay according to the invention.

Fig. 6

a representation similar to Figure 2 of the second embodiment of the relay according to the invention.

Fig. 7

a plan view of the armature in the second embodiment in the direction of arrow C in Figure 5 without contact spring.

Fig. 8

a side view of the armature in the direction of arrow D in Fig. 7;

Fig. 9

a view of the armature in the direction of the arrow E in Fig. 7;

Fig. 10

a representation similar to Figure 3 of the armature with contact spring in the second embodiment of the relay according to the invention.

Fig. 11

a representation similar to Figure 4 in the second embodiment of the relay according to the invention.

Fig. 12

a view in the direction of the arrow F in Figure 6 in the second embodiment of the relay according to the invention.

Fig. 13

a view similar to Figure 1 of a third embodiment of a relay according to the invention.

Fig. 14

an enlarged view of a support region and a region of action in the third embodiment shown in FIG. 13;

Fig. 15

a view in the direction of the arrow G in Fig. 13;

Fig. 16

a representation similar to Figure 2 of the third embodiment of the relay according to the invention.

Fig. 17

an enlarged view of the support area and the action area in the third embodiment of FIG. 16;

Fig. 18

a plan view in the direction of arrow H on the armature of the third embodiment of FIG. 16;

Fig. 19

a section along line 19-19 in Fig. 13;

Fig. 20

a view corresponding to Fig. 15 showing a tilting movement of the armature and

Fig. 21

a representation similar to FIG. 16 in a fourth embodiment of a relay according to the invention.

A first embodiment of a relay according to the invention, shown as a whole in Fig. 1 and 2, comprises a base 10, on which a designated as a whole by 12 electromagnet is held, which has a winding 14, one of the winding substantially enclosed winding core having a pole body 16 and a return body 18 which is connected to the winding core 16 and with a first leg 20 via an end face 22 of the winding 14 and with a transverse to the first leg 20 extending second leg 24th extends transversely to the end face 22 of the winding 14, wherein on this second leg 24 by means of a joint 26, an armature 30 is mounted about a hinge axis 28 which extends with an anchor arm 31 via an end face 22 opposite end face 32 of the winding 14, via which the pole body 16 projects with a pole face 34.

The armature 30 in turn is acted upon by a spring 40 in the direction of a contact-releasing end position shown in FIG. 1, wherein the spring 40 is arranged, for example, on a side of the second leg 24 opposite the winding 14 and, on the one hand, fixed to the second leg 24 connected bearing point 42 and on the other hand acts on a lever arm 44, which extends on a side opposite the armature 30 side of the hinge axis 28 and extending from the armature 30.

To determine the contact-releasing end position, a stop 46 is provided, for example, on the second leg 24, on which the lever arm 44 rests in the contact-releasing end position.

On a side facing the electromagnet 12 of the anchor arm 31 is a designated as a whole with 50 contact spring which extends from a first end 52 to a second end 54 and in a subsequent to the first end 52 fixing region 56 on a fixing surface 58th the armature 30 rests on the anchor arm 31 via a rivet or Welded joint 59 is fixed, wherein the fixing surface 58 of the anchor arm 31 is located on the electromagnet 12 side facing. This connection between the armature 30 and the contact spring 50 forms a first action possibility for moving the contact spring 50 by means of the armature 30th

Subsequent to the fixing region 56, the contact spring 50 extends with a spring arm 60 between the fixing region 56 and the second end 54, to which an actuating region 62 of the contact spring connects, to which a first contact element 70 is held, which is used to make an electrical contact can be moved in the direction of a second contact element 72 and, as shown in Fig. 2, in the contact-making end position, in contact with this can be brought.

The second contact element 72 sits on a base 74, which in turn is likewise held on the base 10.

As shown in FIG. 1, the spring arm 60 has an engagement region 80, which extends in the contact-releasing end position of the armature 30 at a distance from a support region 82 of the anchor arm 31, so that the support region 82 can not act on the action region 80.

This support region 82 includes, as shown again in FIGS. 3 and 4 for clarity, three support edges 84, 86, 88, which are arranged by the extending in the contact-free end position spring arm 60, namely from the impact area 80 thereof, with increasing distance, wherein the first support edge 84 is formed by a relative to the fixing surface 58 recessed first surface 94, which at the first support edge 84 in a second surface 96, which is even stronger relative to the fixing surface 58th and the impact area 80 is reset. Furthermore, the second surface 96 extends to the second support edge 86 and merges therewith into a third surface 98, which is set back even further in relation to the fixing surface 58 and also to the action region 80 in the contact-releasing position. This third surface 98 then in turn merges into a fourth surface 100 at the third support edge 88, wherein the fourth surface 100 has the greatest distance from the fixing surface 58 and the exposure region 80 in the non-contact end position of the armature 30.

As shown in Fig. 3, also has the fixing portion 56 of the contact spring 50 is still a recess 102 through which passes the transition of the armature 30 from the contact-releasing end position in the contact end position of the pole body 16 with the pole face 34, so that the anchor arm 31st of the armature 30 can come to rest with a Polanlagefläche 104 on the pole face 34.

In order to be able to reliably separate the contact elements 70, 72 from each other even in the event of sticking when loosening the contact elements 70, 72, the contact spring 50 is still provided with a holding element 106 in the region of the second end 54, which preferably has an upper side 108 facing away from the electromagnet 12 of the armature 30 engages and then comes to rest on the upper side 108 when the spring arm 60 would move too far away from the armature 30, in particular the support region 82, due to adhesive contact elements 70, 72.

Preferably, the holding member 106 is formed so that it is then applied to the top 108 straight when the spring arm 60 is in the contact-releasing end position of the armature 30 in its undeformed position and the impact area 80 thereof extends at a distance from the support portion 82 of the armature 30.

Now, when the electromagnet 12 is energized, the armature 30 is attracted by the pole body 16 and pivots against the force of the spring 40 about the hinge axis 28 of the joint 26 so that the Polanlagefläche 104 moves in the direction of the pole face 34.

In this movement of the armature extends - as long as the contact elements 70, 72 are still not abutting each other - the spring arm 60 without deformation and thus with the action region 80 at the same distance from the support portion 82 of the armature 30, which also in the contact-releasing position of the armature 30th is present.

Only when the contact elements 70 and 72 touch, arises with increasing pivoting of the armature 30 in the direction of its contact-making end position, a contact force 110, which presses the first contact element 70 against the second contact element 72, wherein this contact force 110 is dependent on the deformation of the between the fixing region 56 and the actuating portion 62 extending spring arm 60th

This contact force 110 increases with increasing deformation of the spring arm 60 and increasing movement of the action region 80 in the direction of the support region 82.

If the deformation is strong enough, then the action area 80 comes into abutment with an action point 114 at the support edge 84, while the action area 80 does not yet bear against the other support edges 86 and 88.

This additional support of the spring arm 60 in the region of the action point 114 on the support edge 84 on the armature 30 is a second possibility of action of the anchor arm 31 on the spring arm 60 and has the consequence that the contact force generated by the spring arm 110 110 now of the deformation of the spring arm 60 between the action point 114 and the actuating portion 62 is dependent, wherein this portion has a length L1 which is smaller than a length L0 of the spring arm 60th

This has the consequence that the portion L1 of the spring arm 60 is stiffer and thus the further deformation of this portion of the spring arm 60 with the length L1 leads to a larger contact force 110, as the contact force 110, without additional support of the spring arm 60 at the point of action 114 would occur through the support edge 84.

A further deformation of the spring arm 60, in particular of the section L1 thereof, results in that the action region 80 comes into abutment with and is supported by a second action point 116 on the second support edge 86, so that a third possibility of action of the armature arm 31 on the spring arm 60 and the still free resilient portion of the spring arm 60 is only the portion between the action point 116 and the actuating portion 62 whose length L2 is smaller than the length L1.

Thus, this portion of the spring arm 60 behaves even stiffer than the portion having the length L1 and the contact force 110 generated by deformation thereof becomes even larger.

A further increase in the contact force 110 can still be achieved if the further deformation of the spring arm 60 causes the impact area 80 with the action point 118 at the third support edge 88 comes to rest, and by a fourth possibility of action thus remaining, free-floating Section of the spring arm 60 has the length L3, which is even shorter than the length L2, so that the contact force 110 is even greater.

In this case, the distance between the supporting edge 88 and the action region 80 of the spring arm 60 is selected so that the impact area 80 at the point of action 118 only shortly before reaching the contact position of the armature 30 comes to rest, so that in the contact-making end position of the armature 30, in which this rests with the Polanlagefläche 104 on the pole face 34, the maximum contact force 110 is available to press the contact elements 70 and 72 against each other.

The advantage of the inventive increase in the contact force 110 by successive application of the action region 80 on the support edges 84, 86 and 88 has the advantage that the contact force 110 can be successively increased, wherein the successive increase in the contact force 110 even with increasingly smaller distance between the Pole surface 34 and the Polanlagefläche 104 takes place and thus uses the increasing magnetic force with decreasing air gap.

Thus, the armature 30 must also absorb the opposing forces arising from the increasing contact forces 110 only when the air gap between the pole face 34 and the Polanlagefläche 104 is small enough and thus acting on the armature 30 holding force of the electromagnet 12 is sufficiently large, so that they can safely overcome the opposing forces.

This makes it possible to have contact forces 110 between the contact elements 70 and 72 in the contact-making position of the armature 30 take effect, which is optimally adapted to the force acting between the pole body 16 and the armature 30 holding force due to lying substantially at zero Air gap between the pole face 34 and the Polanlagefläche 104 reaches its maximum value in the contact-making end position of the armature, while the holding force at a larger air gap between the pole face 34 and the Polanlagefläche 104 is lower.

In a second embodiment of a relay according to the invention, shown in FIGS. 5 to 12, those parts which are identical to those of the first embodiment, provided with the same reference numerals, so that with respect to the description of the same fully incorporated by reference to the statements on the first embodiment becomes.

In contrast to the first exemplary embodiment, as shown in FIG. 12, two first contact elements 70a and 70b are provided, which are seated on a contact bridge 120 and can be brought into abutment against two second contact elements 72a and 72b, which in their turn on their own sockets 74a and 74b are held on the base 10.

That is, in this case, the contact spring 50 moves with its operating portion 62, the contact bridge 120 with the first contact elements 70a and 70b between a non-contact and a contact-giving position.

In order to obtain the most uniform possible contact with the second contact elements 72a and 72b, it is advantageous if the contact bridge 120 with the first contact elements 70a and 70b is tiltable about a tilt axis 122, so that when making contact between the second contact elements 72a and 72b the contact forces 110a and 110b acting between the respective first and second contact elements 70a and 72a and 70b and 72b are equal.

The tilting axis 122 is, as shown in FIGS. 7 to 9, created by the fact that the first surface 94, the second surface 96 and the third surface 98 are not only set back relative to the fixing surface 58, but in the direction of the spring arm 60th rising roof-shaped or pointed and each forming a support edge, 124, 126 and 128, which extend parallel to a line 130, and also lie in a plane 132, which is preferably perpendicular to the hinge axis 28 and perpendicular to the entire support region 82 and surrounding Thus, the spring arm 60, even if it rests against the supporting edges 84 and / or 86 and / or 88, still has the possibility of tilting about the tilting axis 122 and thus additionally with the actuating region 62 to perform a torsion about the tilting axis 122 so that the contact forces exerted by both first contact elements 70a and 70b 110a and 110b are substantially the same size.

In order likewise to achieve a simple release of the first contact elements 70a and 70b from the second contact elements 72a and 72b, two holding elements 106a and 106b are preferably provided, as shown in FIG. 12, which engage over the upper side 108 and cause excessive movement of the Prevent spring arm 60 away from the support area 82.

In a third embodiment of a relay according to the invention, shown in Figs. 13 to 18, also those elements which are identical to those of the preceding embodiments, provided with the same reference numerals, so that with respect to the description thereof in full to the comments on the preceding embodiments Reference is made.

In the third embodiment, an electromagnet 12 is provided on the base 10, which has two magnetic pole plates 140 ₁ and 140 ₂ , which are arranged on a two windings 14 ₁ and 14 ₂ passing core with the pole bodies 16 ₁ and 16 ₂ , so that with the windings 14 ₁ and 14 ₂ two oppositely directed magnetic fields can be generated, depending on which of the windings 14 ₁ or 14 _{2 is} energized.

From magnetic pole plate 140 ₁ to magnetic pole plate 140 ₂ , a preferably with its ends 141 ₁ and 141 ₂ to this fitting permanent magnet 142, which is magnetized such, an attraction of the armature 30 in the region of both ends 141 ₁ and 141 _{2 of} the permanent magnet 142 takes place. One way of magnetizing the permanent magnet is in the DE 21 48 377 A described. Another possibility provides that one pole side 144 of the permanent magnet 142 faces on one side facing the windings 14 ₁ , 14 ₂ and another pole side 146 faces away from the windings 14 ₁ , 14 ₂ and the armature 30.

A fixation of the unit of electromagnet 12 and permanent magnet 142 via supports 148 ₁ , 148 ₂ which are suitably formed on the magnetic pole plates 140 ₁ , 140 ₂ are formed. (Fig. 15)

The armature 30 is pivotally mounted about the hinge axis 28 via the hinge 26 in this case on the permanent magnet 142 and thus on the permanent magnet 142 relative to the base 10 and includes two armature arms 31 ₁ and 31 ₂ , which extend on both sides of the hinge axis 28, and Although up to the magnetic pole plates 140 ₁ and 140 ₂ wherein each one of the armature arms 31 ₁ , 31 ₂ with its Polanlagefläche 104 ₁ and 104 ₂ on the pole face 34 ₁ and 34 ₂ , formed by one end 141 ₁ or 141 ₂ of Permanent magnets 142 and a contact surface 149 ₁ , 149 _{2 of} the respective magnetic pole plate 140 ₁ and 140 ₂ can be applied, so that two stable positions exist, namely a stable position when the Polanlagefläche 104 ₁ rests against the pole face 34 _{1 of} the magnetic pole 140 ₁ and the other stable position in which the pole abutment surface 104 ₂ abuts the pole face 34 _{2 of} the magnetic pole plate 140 ₂ .

The electromagnet 12 now causes, depending on which of the windings 14 ₁ , 14 _{2 is} energized a weakening of the magnetic field at one of the pole faces 34 ₁ or 34 ₂ and a strengthening of the magnetic field at the other of the pole faces 34 ₂ and 34 ₁ , so that either one anchor arm 31 ₂ or the other anchor arm 31 _{1 can be applied} to the pole faces 34 ₂ or 34 ₁ . This position is then held by the permanent magnet 142 even after switching off the energization of one of the windings 14 ₁ , 14 ₂ .

Also in the third embodiment, the armature 30 is provided with the contact spring 50, which rests in a hinge 26 cross-section of the armature 30 with the fixing portion 56 on the fixing surface 58 of the armature 30 to form a first possibility of action and each parallel to the armature arms 31st ₁ and 31 ₂ extends extending spring arms 60 ₁ and 60 ₂ , which extend to their respective second ends 54 ₁ and 54 ₂ .

Preferably, the armature arms 31 ₁ and 31 ₂ and the spring arms 60 ₁ and 60 _{2 are formed} symmetrically to a plane passing through the hinge axis 28 symmetry plane 147, so that the provided on the spring arms 60 ₁ and 60 ₂ impact regions 80 ₁ and 80 ₂ and the corresponding support portions 82 ₁ and 82 _{2 of} the armature arms 31 ₁ , 31 ₂ are formed identical to the formation of further action possibilities.

Expediently, both spring arms 60 ₁ and 60 _{2 are provided} with actuating portions 62 ₁ and 62 ₂ , although, however, in the third embodiment, only the actuating portion 62 ₂ carries a contact bridge 120 with first contact elements 70, which can be brought into contact with second contact elements 72 shown in Fig. 13.

Further, in the third embodiment of the spring arm 60 ₁ with its operating portion 62 _{1 can be placed} on a support bearing 150, which is arranged at the same distance from the hinge axis 28, as the second contact elements 72a ₂ and formed such that at this resting on this operating portion 62 _1st the spring arm 60 ₁ generates a contact force 110 which is substantially identical to that of the contact force acting on the contact elements 70 a ₂ and 72 a _{2 in the} contacting position thereof.

In the third embodiment, the cooperation of the armature 30 and the contact spring 50, if one considers the armature arms 31 ₁ and 31 ₂ and the spring arms 60 ₁ and 60 ₂ individually, just as in the preceding embodiments.

In the third embodiment, due to the arrangement of the second contact elements 72a ₂ on a Polanlagefläche 104 side facing away from the Ankerarms 31 ₂ anchor arm 31 ₂ in the contact-releasing end position when the Polanlagefläche 104 ₂ of Ankerarms 60 ₂ on the pole face 34 _{2 of} the magnetic pole 140 ₂ is applied and thus the air gap is substantially zero. In this case, the spring arm 60 ₂ extends in the same manner as described in connection with the contact-releasing position of the armature 30 as described in the first and second embodiments, with its impact area 80 ₂ at a distance from the support portion 82 _{2 of} the anchor arm 31 _second

In addition, the armature arm 31 _{1 is} in a position which would correspond in the terminology of the preceding embodiments of a contact-making end position, wherein the Polanlagefläche 104 _{1 is} at the maximum distance from the pole face 34 _{1 of} the magnetic pole plate 140 ₁ . However, the spring arm 60 ₁ rests with its action region 80 ₁ on the support region 82 _{2 of} the armature arm 31 ₁ when the actuation region 62 ₁ with the contact force 110 ₁ acts on the support bearing 150, which simulates contact elements on the armature arm 31 ₁ in this case. The contact force 110 ₁ has a total of the armature 30 acting counterforce result.

When switching the relay is carried out by energizing the windings 14 ₁ or 14 ₂ tilting of the armature 30 such that this now with the Polanlagefläche 104 ₁ rests against the pole face 34 ₁ , while the Polanlagefläche 104 ₂ at the maximum distance from the pole face 34 _second stands. In this case, the armature arm 31 ₂ is now in its contact-making end position, while the armature arm 31 _{1 is} in its position corresponding to a contact-releasing end position. (Figures 16 and 17)

The spring arm 60 ₁ may be formed in this case so that its operating portion 62 _{1 is} at a distance from the support bearing 150 to create the Symmetrieebene 147 exactly symmetrical power relations. But it is also conceivable that the actuating portion 62 ₁ remains applied to the support bearing 150, but in the position shown in Fig. 15 with a vanishing or no force on the support bearing 150 acts, while the actuating portion 62 ₂ with the contact force 110 ₂ on the contact element 70a ₂ acts, and presses this with the contact force 110 ₂ against the contact element 72a ₂ .

In the third embodiment, in particular the action areas 80 ₁ and 80 ₂ and the support portions 82 ₁ and 82 _{2 are formed} in the same or similar manner as in the first or second embodiment, as shown in FIGS. 14 and 16, but in this case only two support edges 84 and 86 are present, the corresponding action points 114 and 116 produce, but the effect of which is exactly the same as in the first embodiment, so that the contents of the comments on the first embodiment can be made fully.

As shown in FIGS. 18 to 20, the armature 30 is pivotable not only about the articulation axis 28 in the area of the articulation 26, but also about the tilting axis 122 perpendicular to the articulation axis 28, which is most easily realized by virtue of the fact that Anchor 30 abuts with a spherical cap-shaped elevation 152 on a flat side 154 of the permanent magnet 142 and thus tiltable both about the hinge axis 28 and about the tilt axis 122.

In order to limit the tilting movement, protrusions 156 and 158 are preferably provided in the direction of the articulation axis 28 on both sides of the spherical cap-shaped elevation 152, which limit a tilting movement about the tilting axis 122 to a smaller angle than the pivoting movement about the articulation axis 28.

In a fourth embodiment shown in Fig. 21, all the parts which are identical to those of the third embodiment or the above embodiments are given the same reference numerals, so that reference may be made to the foregoing embodiments with respect to the description thereof in full.

In contrast to the third embodiment, the fourth embodiment is so far completely symmetrical to the symmetry plane 147, since both sides are disposed the same to the control sections 62 ₁ and 62 ₂ of the spring arm 60 ₁ and 60 ₂ contact bridges 120 ₁ and 120 ₂ provided with first contact members 70a ₁ and 70a ₂ which can be brought into contact with second contact elements 72a ₁ and 72a _2, in each case alternately, as already described in connection with the third embodiment.

In addition, the armature arms 31 ₁ and 31 _{2 are formed} in the same manner as in the third embodiment and provided with the support portions 82 ₁ and 82 ₂ , to which the action areas 80 ₂ and 80 _{1 can be brought} to bear alternately, depending on which Anchor arm 31 ₁ and 31 _{2 of} the armature 30 is in the contact-releasing end position or the contact-making end position.

Claims (23)

Comprising relay
a base (10), an electromagnet (12) arranged on the base (10), an armature (30) with at least one pivotally mounted on the base (10) and by means of the electromagnet (12) between a contact-releasing end position and a contacting end position movable armature arm (31), a contact spring (50) which can be moved by means of a first action possibility on the part of the armature (30) and which extends with at least one spring arm (60) to at least one actuation area (62), at least one first contact element (70), on which the contact spring (50) acts by means of the at least one actuation region (62) and at least one second contact element (72) arranged on the base (10), on which the first contact element (70) in the contact-setting position of the armature arm (31) a contact force (110) which can be generated by deformation of the contact spring (50) can be applied,
characterized in that the armature arm (31) has a support region (82) facing the spring arm (60) for acting on an action region (80) of the spring arm (60) such that the spring arm (60) is in the contact-releasing position of the armature arm (31). extends with the impact area (80) at a distance from the support region (82) and that at least in a contact-making end position of the anchor arm (31) of the anchor arm (31) by acting with the support region (82) on the action region (80) of the spring arm (60) has a further possibility of action on the contact spring (50), which in the sense of an amplification of the contact force (110) generated by the contact spring (50). Relay according to Claim 1, characterized in that the support region (82) is arranged on the armature arm (31) in such a way that the area of action (80) of the spring arm (60) is reached after a first contact with the contact elements (70, 72) and before reaching contact end position of the armature (30) can be acted upon. Relay according to Claim 1 or 2, characterized in that the support region (82) has at least one support point (84, 86, 88), with which the support region (82) is exposed to an action point (114, 116, 118) of the action region (80). on the spring arm (60) acts. Relay according to Claim 3, characterized in that at the support point (84, 86, 88) and the point of action (114, 116, 118) of the armature arm (31) and the spring arm (60) cooperate in such a way that a spring action of the spring arm (60 ) is limited essentially to a between the action point (114, 116, 118) and the actuating portion (62) lying portion of the spring arm (60). Relay according to Claim 3 or 4, characterized in that the support region (82) has a plurality of support points (84, 86, 88) which act on a plurality of action points (114, 116, 118). Relay according to Claim 5, characterized in that upon a movement of the armature arm (31) from the contact-releasing end position into the contacting end position, the plurality of support points (84, 86, 88) act successively on the corresponding action points (114, 116, 118). Relay according to Claim 6, characterized in that the consecutively interacting support points (84, 86, 88) and action points (114, 116, 118) cause an ever-increasing contact force (110). Relay according to Claim 6 or 7, characterized in that the successively cooperating support points (84, 86, 88) and action points (114, 116, 118) are arranged at an increasingly smaller distance from the actuation area (62). Relay according to one of Claims 5 to 8, characterized in that the supporting points (84, 86, 88) act on the corresponding points of action (114, 116, 118) only after touching the contact elements (70, 72). Relay according to one of the preceding claims, characterized in that the support area (82) or the action area (80) are step-shaped and step edges (84, 86, 88) thereof form the support points or points of action. Relay according to one of the preceding claims, characterized in that the support region (82) and the action region (80) permits a movement of the spring arm (60) about a tilting axis (122) extending transversely to the articulation axis (28) of the armature (30) are formed. Relay according to Claim 11, characterized in that the support region (82) and the action region (80) cooperate maximally substantially in the form of a line in the direction of the tilting axis (122). Relay according to Claim 12, characterized in that the support region (82) and the action region (80) interact in a substantially point-like manner. Relay according to one of Claims 11 to 13, characterized in that the support region (82) and the action region (80) have an extension in the direction parallel to the joint axis (28) which is smaller than one quarter of a distance of the first contact elements (70a, 70b) in the direction of the hinge axis (28). Relay according to one of the preceding claims, characterized in that the spring arm (60) of the contact spring (50) is arranged on a side of the armature arm (31) facing the respective second contact element (72). Relay according to one of the preceding claims, characterized in that the contact spring (50) is arranged on a side of the armature (30) facing the electromagnet (12). Relay according to Claim 16, characterized in that the contact spring (50) has a recess (102) in the region of the pole contact surface (104). Relay according to one of Claims 1 to 15, characterized in that the contact spring (50) is arranged on a side of the armature (30) opposite the electromagnet (12). Relay according to Claim 18, characterized in that a pole contact surface (104 ₁ ) of the armature (30) which bears against the electromagnet (12) in the contact-making position is provided on a side of the joint (26) opposite the contact elements (70, 72) for pivotable mounting of the armature (30) is arranged. Relay according to Claim 18 or 19, characterized in that the electromagnet (12) has two magnetic poles (140 ₁ , 140 ₂ ), each of which cooperates with an armature arm (31 ₁ , 31 ₂ ) of an armature (30) designed as a rocker. Relay according to one of the preceding claims, characterized in that the actuating region (62) of the contact spring (50) is coupled to the armature (30) via a retaining element (106). Relay according to Claim 21, characterized in that the holding elements (106) allow such relative movement of the spring arm (60) relative to the armature arm (31) that the support region (82) and the action region (80) abut each other or can be spaced apart , Relay according to Claim 21 or 22, characterized in that the holding element (106) is designed as a stop element permitting movement of the spring arm (60) relative to the armature (30).

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