DE102010043352A1 - Contact arrangement for a relay with two load current paths and relays with contact arrangement - Google Patents

Abstract

The invention relates to a contact arrangement (1) for a relay (28) and a relay (28) with a contact arrangement (1) for switching a high load current. In order to minimize switching forces caused by the load current, the invention provides that the contact arrangement (1) has at least two electrically separate load current paths (14, 15), the relay (28) having a pair of counter contacts (33, 33 'and 34, 34 ') per load current path (14, 15).

Description

The invention relates to a contact arrangement for a relay for switching a high load current, with an armature and a motion-transmitting connected to the armature switching device for conducting the load current. Furthermore, the invention relates to a relay for switching a high load current, with an actuator for generating switching forces acting on an armature and with to be bridged during a switching operation mating contacts.

Contact arrangements for a relay and relays for switching a high load current are widely used. For switching the load current counter contacts of load current terminals of the relay are bridged by the contact arrangement. These relays are used, for example, for switching drive power of an electrically operable automobile.

Due to the current displacement in the contact point of the contact pieces (current quantity) act on the contact pieces repulsive forces. Likewise, the self-field of the power supply acts on the Lorenzkraft on the moving live parts. All these forces are proportional to the square of the impressed current. The linear relationship between force and current square is in the order of the magnetic field constant μ0, d. H. from a current flow of 1000 A on the contact system, a diverging force of several Newton acts. Due to the quadratic dependence on the current, in the case of large overcurrents, the repulsive force can cancel the provided closing force. The contact is pressed by the current flow. Relieving the contact by large currents leads to a rapid increase in the contact resistance and thus to an undue increase in power consumption in the contact point. This is either the cause of an immediate welding of the contact pieces or leads to complete destruction of the switching device. At the moment of lifting the contact material evaporates abruptly under arc effect, the current flow breaks down, the contacts close again and the process repeats itself.

It is therefore an object of the present invention to provide a contact arrangement for a relay and a relay, in which the forces caused by the high currents occur only in attenuated form.

The object is achieved for the above-mentioned contact arrangement according to the invention that the switching element has at least two electrically isolated from each other, preferably insulated load current paths for the load current. For the relay according to the invention the object is achieved in that the relay is formed with a contact arrangement according to the invention, wherein the relay has a pair of mating contacts per current path.

The use of multiple current paths and the assignment of mating contact pairs to a current path, the current flow through the individual current paths and their associated mating contacts is reduced. If, for example, two load current paths are used, then in each case half of the load current can flow through one of the load current paths. At a same leading to high load current, the necessary force to keep closed the switching connection with a contact arrangement according to the invention and a relay according to the invention is halved.

The solution according to the invention can be further improved by various configurations which are advantageous in each case and can be combined with one another as desired. These embodiments and the advantages associated with them will be discussed below.

The current paths can be arranged in a closed switching state of the relay in a parallel circuit. This ensures that in each case only a part of the high load current flows through one of the load current paths.

In order to bridge spaced-apart mating contacts of the relay with the switching device, each of the load current paths may have a contact bridge of the switching element. The contact bridge may for example be cylindrical and in particular bar-shaped, wherein provided on the contact bridge switching contacts can be arranged on one side of the contact bridge. For example, the switch contacts may be spaced as far apart as possible on the contact bridge and away from the armature and made of a material that resists switching sparks or switching arcs. As a result, the switching contacts wear less than, for example, switching contacts made of copper as a result of many switching operations.

In order to prevent the switching operation, in particular a process for closing the relay, is affected by so-called bouncing of the switching contacts of the switching element and the mating contacts of the relay, the contact bridges can be resiliently mounted. In particular, the contact bridges can be deflected relative to the armature elastically from its rest position.

The switching element may be formed with a bearing element rigidly connected to the armature, on which the contact bridges are resiliently mounted. For example, the bearing element elongated and the contact bridges be connected via spring elements with ends of the bearing element. The spring elements can connect to at least two spaced-apart bearing sections each one of the contact bridges this resiliently with the bearing element. Each of the spring elements can be fastened both to one of the contact bridges and to the bearing element.

By this arrangement of the spring elements, the switching contacts of each contact bridge are substantially independently elastically deflectable. If the geometry of one of the switching contacts has changed more strongly due to wear, for example due to burnup, than the geometry of the other switching contact of the contact bridge, the switching contacts of the contact bridge can nevertheless be brought into electrical contact with the mating contacts.

In order not to conduct the required separation force to open the switching connection via the spring elements, the switching element may have a motion-rigid connected to the armature driver for opening the closed circuit connection. When opening the relay, the driver can forcibly remove the contact bridges of the mating contacts without the required switching forces applied by the spring elements and this may be overloaded thereby. The overload of the spring elements can be prevented, as well as large separation forces are absorbed by the driver. These large separation forces can occur, for example, when the switch contacts are welded to the mating contacts as a result of a switching operation. As a result, a uniform opening of the relay is also ensured, even if different forces for separating individual switching contacts of the respective mating contacts are necessary.

Due to the combination of the resilient mounting of the contact bridges when closing the relay and from the positive movement of the contact bridges generated by the driver when opening the switching connection, the contact arrangement is thus optimally adapted both to the closing operation and to the process for separating the switching connection.

The contact bridges may rest in their rest position with their side facing away from the armature on the driver and be resiliently pressed against the driver. Despite the movable mounting of the contact bridges on the spring elements whose position is well defined relative to the mating contacts. Further, the driver may have guide portions, by which a tilting of the contact bridges can be prevented. The guide portions may be formed for example by bent ends of the driver.

The contact bridges can be pressed against the driver so that the spring elements are biased. At a high bias voltage, the change in the contact force with which the switch contacts are pressed against the mating contacts, even then relatively low when the switch contacts or mating switch contacts are worn out by burning different. In order to arrange the switch contacts and the mating contacts in the relay so that the distance between the respective contacts is sufficient for air insulation, the contact bridges can be elongated and arranged transversely to their longitudinal axes spaced from each other.

For transferring the switching element into a rest-switching position, the contact arrangement can be configured with an armature spring which presses the armature into the rest-switching position in a state of the contact arrangement mounted in the relay. For example, the sleep position may be the open switch position of the relay. Such a relay is also called a closing relay, since in this case the actuator must generate forces to close the relay.

In order to be able to check whether the contact arrangement reaches its rest position when the actuator is inactive, the contact arrangement may comprise a position sensor. The position sensor can be formed immovable relative to the driver and, for example, attached to the anchor. When the position sensor reaches the standby position, it can interact with a detector located in the relay. In operation, the detector may output a signal when the armature has reached or is arranged in its rest-switching position.

In this way it can be checked whether the armature spring has really transferred the switching element in the closed position or whether, for example, welded together switch contacts and mating contacts prevent opening of the switching connection and consequently a return of the switching element in the closed position.

For example, the detector may be configured as a Hall sensor and the position sensor as a magnet interacting with the Hall sensor during operation. Alternatively, optical, capacitive or resistive position sensors and detectors can also be used.

In order to minimize wear of the switching contacts and the mating contacts during switching operations, in particular the wear caused by erosion is to be avoided as far as possible. At the Switching high load currents and in particular when disconnecting the closed switch connection switching arcs may occur in which temperatures of several thousand Kelvin can prevail. In particular, by the thermal energy generated in the arcs, the switch contacts and mating switch contacts can melt and even evaporate. The material removal can lead to a deformation of the contacts and a failure of the relay. Consequently, it is desirable to keep the entry of thermal energy in the contacts as small as possible. In particular, a shortening of the burning time of the arcs, which can be influenced by magnetic fields, can contribute to this. To generate the magnetic fields, the contacts can each be flanked adjacent to at least one magnet and in particular by two magnets. For example, a pair of magnets may flank a switching pair of a switching contact and a mating contact. The magnets may be formed, for example, as permanent magnets in the form of neodymium magnets.

Since the high load current to be switched flows only proportionally through the respective contact bridges, they can be reduced in cross-section compared to a contact bridge, which has to conduct the entire high load current. Due to the smaller cross-section of the contact bridges, the magnets can be arranged closer to the contacts, as a result of which the magnetic field in the region of the contacts and the possibly occurring arcs is stronger. The burning time of the arcs can thereby be reduced to 0.1 seconds or less.

The invention is explained below by way of example with reference to embodiments with reference to the drawings. The different features of the embodiments can be combined independently of each other, as has already been explained in the individual advantageous embodiments.

Show it:

1 a schematic representation of a first embodiment of the contact arrangement according to the invention in a perspective view;

2 a schematic sectional view of a first embodiment of the relay according to the invention;

3 a schematic exploded view of a portion of the relay according to the invention 2 ;

4 a schematic perspective view of mating contacts of the relay of the embodiment of 2 ,

First, structure and function of a contact arrangement according to the invention 1 with reference to the embodiment of the 1 described. Here is the contact arrangement 1 for a relay for switching a high load current schematically with an armature 2 and a switching member 3 shown, with the anchor 2 and the switching element 3 via an actuating rod 4 can be rigidly connected. Furthermore, the contact arrangement 1 another anchor spring 5 , which is formed in the embodiment shown as a coil spring include. The operating rod 4 can through the helical anchor spring 5 be guided and together with the anchor spring 5 from the anchor 2 in the direction of the switching element 3 protrude.

The switching element 3 is exemplary with two contact bridges 6 . 7 shown. The contact bridges 6 . 7 can each have two switching contacts 8th . 8th' . 9 . 9 ' have and electrically isolated from each other in the switching device 3 be arranged. The contact bridges 6 . 7 In the illustrated embodiment, for example, are elongate and shaped, for example, beam-shaped, wherein the switching contacts 8th . 8th' . 9 . 9 ' on from the anchor 2 pointing away pages 10 . 11 in the region of lying in the longitudinal direction L1, L2 ends 12 . 12 ' . 13 . 13 ' can be arranged. Between the switch contacts 8th . 8th' and 9 . 9 ' each of the contact bridges 6 . 7 can ever a load current path 14 . 15 be arranged, whose course through the contact bridges 6 . 7 in the 1 is shown by a dash-dotted line.

The contact bridges 6 . 7 can be arranged parallel to each other and transversely to their longitudinal directions L1, L2 spaced from each other in the switching device 3 be held. In order to minimize a so-called bouncing when closing the relay, the contact bridges 6 . 7 resilient in the switching element 3 be stored. Due to the resilient mounting of the contact bridges 6 . 7 These can be relative to the anchor 2 parallel to a closing direction D, in particular on this to or away from this, be elastically deflectable. Here the closing direction D points from the anchor 2 to the switching element 3 ,

For positioning the contact bridges 6 . 7 at a distance A transverse to their longitudinal directions L1, L2 to each other, the switching element 3 a bearing element 16 have, at which the contact bridges 6 . 7 are resiliently mounted. The bearing element 16 can be motionless with the anchor 2 connected and, for example, at the extending in the closing direction D actuating rod 4 be fixed. The bearing element 16 may be plate-shaped and substantially perpendicular to actuating rod 4 extend, wherein the actuating rod 4 through a central region of the bearing element 16 can protrude through. From the operating rod 4 pointing away ends 17 . 18 of the bearing element 16 can be parallel to the actuating rod 4 and from the anchor 2 be oriented away. The ends 17 . 18 can be formed as guide sections and a displacement of the contact bridges 6 . 7 prevent each other away, at least when the contact bridges 6 . 7 from her in the 1 shown rest position R elastic in the direction of the bearing element 16 are distracted.

The contact bridges 6 . 7 can have at least one spring element 19 on the bearing element 16 be stored. For example, the spring elements 19 . 19 ' Have in significant S-shaped ends, which are arranged mirror-symmetrically to each other and their successive assigning sheets can be integrally connected to each other. The free and facing away arches can at one of the contact bridges 6 . 7 be attached.

The spring element 19 may comprise one or more springs, which may be formed, for example, leaf spring-shaped. A middle region of such a leaf spring element 20 can be on the bearing element 16 be fixed, the ends of which are from the bearing element 16 and from the anchor 2 arch away and at one of the contact bridges 6 . 7 can be fixed. In particular, free ends can 21 of the leaf spring element 20 with spaced apart bearing sections B, B 'of each contact bridge 6 . 7 be fixed. The bearing sections B, B 'can on from the switch contacts 8th . 8th' . 9 . 9 ' pointing away pages 22 the contact bridges 6 . 7 designed and for captive connection with the spring elements 19 . 19 ' be designed. By such an arrangement of the spring element 19 can the ends 12 . 12 ' . 13 . 13 ' be stored substantially independently of each other elastically.

The switching element 3 can with a driver 23 be formed, through which the contact bridges 6 . 7 away from mating contact elements are movable. The driver 23 can be similar to the bearing element 16 be formed and arranged mirror-symmetrically to this, wherein the contact bridges 6 . 7 between the driver 23 and the bearing element 16 can be arranged. In their rest position R, the contact bridges 6 . 7 with theirs from the anchor 2 pointing away pages 10 . 11 at the driver 23 abut and possibly by the prestressed spring elements 19 . 19 ' against the driver 23 be pressed. By the bias of the spring elements 19 . 19 ' can be ensured that the switching contacts 8th . 8th' . 9 . 9 ' in the closed switching state of the relay always rest with a substantially equal force on mating contacts, even if the shape of the switching contacts 8th . 8th' . 9 . 9 ' for example, by burning should have changed.

From the other contact bridge 6 . 7 way-pointing pages 24 . 25 the contact bridges 6 . 7 can at ends 26 . 27 of the driver 23 issue. The ends 26 . 27 may be formed as guide portions for the contact bridges and parallel to the actuating rod 4 be arranged running and the contact bridges 6 . 7 lead in an elastic deflection so that they are not tilted away from each other.

The bearing element 16 and the driver 23 can be at a constant distance from each other on the actuating rod 4 be fixed.

2 shows a first embodiment of a relay according to the invention 28 with the contact arrangement 1 of the embodiment of 1 , For elements that function and / or structure the elements of the embodiment of 1 correspond, the same reference numerals are used. For brevity, only the differences from the embodiment of 1 received.

The relay 28 is shown in an open switching position, which is a rest position S of the contact arrangement 1 in the relay 28 equivalent. In the neutral position S is the anchor 2 through the anchor spring 5 of counter contacts of the relay 28 pressed away. The relay 28 is therefore designed as a closer, which does not conduct the load current in the non-switched state. Of course, the relay can 28 also be designed as an opener or with a changeover contact.

The essentially cylindrical and, for example, circular-cylindrical armature 2 has at its to the switching element 3 pointing one end from a central opening 29 away from the projecting collar 30 on. One from the switching element 3 pointing away and extending from the collar cylindrical portion 31 is with a smaller diameter than the collar 30 trained and in a guide sleeve 32 of the relay 28 arranged. The anchor spring 5 pushes the anchor 2 this designed as a normally closed relay 28 of mating contacts of the relay 28 away, with only two mating contacts 33 . 34 are shown. However, the relay can switch to any switching contact 8th . 8th' . 9 . 9 ' a counter contact 33 . 34 exhibit. The mating contacts 33 . 34 can be electrically conductive with each other and with a load current connection 35 of the relay 28 be connected. About the load power connection 35 the load current can be the relay 28 supplied or discharged from this, when the contact arrangement 1 is arranged offset from the illustrated rest position S in the closing direction D. For example, the relay can 28 via a control connection 36 one Control signal to be supplied. Based on the control signal can in the relay 28 arranged and, for example, designed as a coil actuator 37 a force on the anchor 2 create an impacting magnetic field, which is the anchor 2 and thus also the switching element 3 in the closing direction D on the mating contacts 33 . 34 to move.

The central opening 29 of the anchor 2 may in particular be cup-shaped, so that at least the armature spring 5 or the actuating rod 4 at least in sections in the opening 29 can be arranged. Both the operating rod 4 as well as the anchor spring 5 can at the bottom of the opening 29 at anchor 2 be fixed. In the illustrated embodiment, the reason is the opening 19 open and, for example, formed as a bore with which the actuating rod 4 screwed or otherwise can be firmly connected.

At one of the switching element 3 pointing away end of the anchor 2 can be a position transmitter 38 be arranged in the sleep position S with a detector 39 interacts. For example, position encoders 38 and detector 39 be arranged closer together in the rest position S than in other switching positions. In particular, the position sensor 38 as a permanent magnet and the detector 39 be formed as a Hall sensor. The position transmitter 38 Can via a fastener 40 at anchor 2 or for example on the actuating rod 4 be attached. Through this attachment, the position sensor 38 Steady in motion Especially with regard to the driver 23 in the relay 28 be provided. Because the driver 23 the contact bridges 6 . 7 When changing a closed switching state in the open or closed state shown S forcibly leads, it is ensured that the switching position of the relay is always open when the position sensor 38 near the detector 39 is arranged.

The contacts 8th' and 33 such as 9 ' and 34 lie in pairs opposite. Both the contact pair 8th' . 33 as well as the couple 9 ' . 34 is between two permanent magnets 42 arranged. The magnetic field of the permanent magnets 42 interferes with the formation and / or maintenance of switching arcs, which when opening the closed connection of switching contact 8th' . 9 ' and mating contact 33 . 34 may occur. Consequently, switching arcs burn shorter than without permanent magnets 41 , resulting in less heat energy in the involved contacts 8th' . 9 ' . 33 . 34 is introduced and wear less as a result of burning.

Both the load current connection 35 as well as the permanent magnets 41 are in the 2 floating within a switching chamber 42 of the relay 28 shown. For fixing at least the load current connection 35 and the permanent magnet 41 For example, the relay may have at least one fixing member, which is shown in the following figures.

The switching chamber 42 can through a mounting plate 43 from a control chamber 44 in which the actuator 37 and the anchor 2 are arranged to be separated. Through the mounting plate 43 can the actuating rod 4 from the control chamber 44 into the switching chamber 42 protrude.

The relay 28 can with a the switching chamber 42 and the control chamber 44 enclosing housing 45 be formed, without the mounting plate 43 a continuous recording volume for the remaining components of the relay 28 can train. At least the switching chamber 42 can through a in the housing 45 provided mounting opening 46 be accessible from the outside. In the illustrated embodiment, the mounting opening 46 through a lid 47 locked. The housing 45 itself as well as in the case 45 arranged components of the relay 28 can be so interconnected that moisture does not enter the case 45 or from a portion of the housing 45 can penetrate into another subarea. Thus, the use of the relay 28 even in humid environments, eg. B. in the engine compartment of an automobile, be guaranteed.

3 shows parts of the relay 28 of the embodiment of 2 without housing 45 in an exploded view.

In the 3 is the actuator 37 in a headband 48 shown mounted, with the headband 48 to the mounting plate 43 open and with this open end on the mounting plate 43 is attached. The mounting plate 43 closes the open end 48 of the retaining clip.

On the from the actuator 37 opposite side of the mounting plate 43 is the switching element 3 arranged. Each of the switch contacts 8th . 8th' . 9 . 9 ' is transverse to the closing direction D of two permanent magnets 41 flanked essentially in the closing direction D and along the contact bridges 6 . 7 extend. Two magnets 41 are on inner sides of two legs of a substantially U-shaped retaining clip 49 arranged shown. The retaining clip 49 may for example be formed of a magnetically conductive material.

In addition to the load power connection 35 Here is a second load power connection 50 shown, which is similar to the load power connection 35 can be trained. The load connections 35 . 50 are in the closing direction D behind the switching element 3 arranged. In the assembled state of the relay 28 protrude the mating contacts 33 . 34 of the load power connection 35 and the mating contacts of the load power connection 50 into the spaces between two magnets 41 attached to a retaining clip 49 are fixed. The contacts of the pairs of switching contacts 8th . 8th' 9 . 9 ' and mating contacts 33 . 34 can be arranged opposite each other in the closing direction D.

For fixing the magnets 41 and the load power connections 35 . 50 can the relay 28 a fixing organ 51 have, with which the magnets 41 and the load power connections 35 . 50 For example, can be positively connected. The fixing organ 51 can through a retaining bush 52 in the relay 28 be secured against slipping at least transversely to the closing direction D, wherein the retaining sleeve 52 in a circumferential groove of the mounting plate 43 can be fixed.

4 shows the fixative 51 with magnets 41 and load power connections 35 . 50 ,

lands 53 . 54 the load current connections 35 . 50 protrude from the fixative 51 out. The fixing organ 51 is shown in the closing direction D, so that the mating contacts 33 . 34 of the load power connection 35 and the mating contacts 33 ' . 34 ' of the load power connection 50 sticking out of the drawing plane.

In electrically conductive state of the relay 28 are the mating contacts 33 . 33 ' through the contact bridge 6 and the mating contacts 34 . 34 ' through the contact bridge 7 electrically bridged. The contact bridges 6 . 7 are indicated here by dashed lines. The resulting current path 55 for the load current is, inter alia, arranged here in a parallel circuit P and shown in phantom Laststrompfaden 14 . 15 together. The over the load power connections 35 . 50 flowing load current flows in the embodiment shown in each case halfway through one of the load current paths 14 . 15 ,

The fixing organ 52 may be at least partially complementary to the contact bridges 6 . 7 and the driver 23 be educated. In particular, the fixing element 52 a substantially H-shaped receiving area 56 in which the contact bridges 6 . 7 and the driver 23 in the closed state of the relay 28 can be arranged at least partially. In this case, a cross-connection of the H-shaped receiving area 56 as a receiving trough 57 for the driver 23 be designed. The receiving trough 57 can be formed in the closing direction D so deep that the contact bridges 6 . 7 in the closed state of the relay 28 no longer at the driver 23 abut, but elastically deflected and spaced from the driver 23 are arranged. This may be the case even if at least one of the switching contacts 8th . 8th' . 9 . 9 ' or the mating contacts 33 . 33 ' 34 . 34 ' worn out by burnup.

Claims (13)

Contact arrangement ( 1 ) for a relay ( 28 ) for switching a high load current, with an armature ( 2 ) and a motion-transmitting with the anchor ( 2 ) connected switching element ( 3 ) for conducting the load current, characterized in that the switching element ( 3 ) at least two load current paths ( 14 . 15 ) for the load current. Contact arrangement ( 1 ) according to claim 1, characterized in that each of the load current paths ( 14 . 15 ) a contact bridge ( 6 . 7 ) of the switching element ( 3 ) having. Contact arrangement ( 1 ) according to claim 2, characterized in that the contact bridges ( 6 . 7 ) are resiliently mounted. Contact arrangement ( 1 ) according to claim 2 or 3, characterized in that the contact bridges ( 6 . 7 ) relative to the armature ( 2 ) are elastically deflected from its rest position (R). Contact arrangement ( 1 ) according to one of claims 2 to 4, characterized in that the switching element ( 3 ) a motion-stable with the anchor ( 2 ) associated drivers ( 23 ) for opening a closed switching connection of the contact bridges ( 6 . 7 ) with counter contacts ( 33 . 33 ' . 34 . 34 ' ) of the relay ( 28 ) having. Contact arrangement ( 1 ) according to claim 5, characterized in that the contact bridges ( 6 . 7 ) in the rest position (R) with its from the anchor ( 2 ) facing away ( 10 . 11 ) at the driver ( 23 ) and spring against the driver ( 23 ) are pressed. Contact arrangement ( 1 ) according to one of claims 2 to 6, characterized in that the contact bridges ( 6 . 7 ) are elongated and spaced transversely to their longitudinal axes (L1, L2) are arranged from each other. Contact arrangement ( 1 ) according to one of claims 2 to 7, characterized in that each of the contact bridges ( 6 . 7 ) has at least two bearing sections (B, B ') over which the contact bridge ( 6 . 7 ) is spring-mounted. Contact arrangement ( 1 ) according to one of claims 5 to 7, characterized by a relative to the driver ( 23 ) immovably shaped position sensor ( 38 ). Relay ( 28 ) for switching a high load current, with an actuator ( 37 ) for generating on an anchor ( 2 ) acting switching forces and with to be bridged during a switching operation mating contacts ( 33 . 33 ' . 34 . 34 ' ), characterized by a contact arrangement ( 1 ) according to one of claims 1 to 8, wherein the relay ( 28 ) a pair of mating contacts ( 33 . 33 ' . 34 . 34 ' ) per load current path ( 14 . 15 ). Relay ( 28 ) according to claim 10, characterized in that the load current paths ( 14 . 15 ) in a closed switching state of the relay ( 28 ) are arranged in a parallel circuit (P). Relay ( 28 ) according to claim 10 or 11, characterized in that the contact bridges ( 6 . 7 ) during a movement of the driver ( 23 ) in one opposite to the closing direction (D) and away from the mating contacts ( 33 . 33 ' . 34 . 34 ' ) pointing opening direction by the driver ( 23 ) are forcibly moved. Relay ( 28 ) according to one of claims 10 to 12, characterized in that the relay ( 28 ) with a detector ( 39 ) which in operation outputs a signal when the armature ( 2 ) is arranged in its rest position (S).

Images