EP0791944B1 - Electromagnetic relay - Google Patents

Abstract

An electromagnetic relay is provided with an electromagnet system with a U-shaped core yoke and an essentially flat armature, which form a working air gap on a longitudinal side underneath the coil winding. One yoke limb lies immediately on the coil winding, so that the make motion of the armature is towards the coil. In this way, a relatively large contact room is formed underneath the yoke limb and a movable contact spring extends approximately parallel under the armature. The contact spring is actuated by the armature which draws an actuating element. The relay enables a relay for high switching capacity with a changeover contact and with large insulating distances between the magnet system and the contact arrangement.

Description

The invention relates to an electromagnetic relay with a Electromagnetic system consisting of an elongated Coil with an axis parallel to a base plane, one U-shaped core yoke, one core leg of which the coil axially penetrated and a yoke leg parallel to it below the coil extends over part of the coil length and forms a pole portion, and a substantially flat one Anchor that is approximately in extension to the yoke leg extends below the spool, with a bearing end portion is stored at the free end of the core and with an opposite pole end section the pole section of the yoke leg to form a working air gap overlaps, further with a contact arrangement with at least a fixed contact attached to a carrier and with a movable contact carried by a switch spring, and with an actuator for transmitting the armature movement the switch spring.

An unpoled relay with the structure mentioned above is known for example from EP 0 375 398 A2. Even there the magnet system contains a U-shaped core yoke, with a Anchor is supported at a core end and with a yoke leg forms the working air gap below the coil. Indeed there is the anchor in the overlap area between the Yoke leg and the coil arranged so that the switching movement the armature is directed outwards from the coil. The Contacts are under the moving armature, which causes does not result in optimal use of space. Accordingly owns the relay there also has only one make contact, while a changeover contact requires additional height. Since there also no very large insulation distances between the magnet system and contact arrangement are possible, the switching capacity is limited.

The aim of the present invention is to provide a relay of the input mentioned type with a flat structure and if possible to create a small volume with only a few individual parts good use of space is achieved. The relay should manage high switching capacities with low excitation power can; the construction should also have good insulation enable between the magnet system and the contact arrangement. The contact arrangement is supposed to be a normally open or NC contact as well as a changeover contact within the enable mentioned low construction.

According to the invention, this goal is achieved with a relay mentioned type achieved in that the pole section of the yoke leg between the armature and the coil is that the switch spring extends substantially below the armature and that the contacts in a below the yoke leg formed in the area in front of the movable anchor end Contact space are arranged.

The inventive design of the magnet system the armature is pulled towards the coil when energized, the switch spring so pulled in that direction. The yoke leg lies with this construction as close as possible to the coil, so that the contact space below the yoke leg more Available height than that below the movable anchor located area. So without further ado low height a changeover contact can be accommodated, while the switch spring is substantially below the movable anchor and approximately parallel to this approximately can extend over the entire length of the relay. The actuator intervenes in the area between clamping and Contact end on the switch spring.

In a particularly expedient embodiment, there is a base body made of insulating material underneath the magnet system, the the switch spring and the carrier or carriers for the Fixed contacts and a partition between the magnet system and the contact arrangement, which only has an opening for the actuator. With appropriate Design of the actuator can of course two openings can also be provided. The partition of the Base body is designed step-like to one side below of the yoke leg to form the higher contact space and on the other hand, there is enough space underneath the anchor for it To provide switching movement. The main body has in an expedient embodiment still down molded, at least partially surrounding the control room Side walls on which a spring support carrying the switching spring and a make contact carrier and / or a break contact carrier anchored in plug-in shafts by plug-in fastening are.

To improve insulation in the breakthrough area the partition can protrude to the underside at its edge Form an insulating collar. The actuator itself in an advantageous embodiment has one on the anchor hooked hook part and an engaging on the switching spring Foot part, the latter with the insulating collar labyrinthine can interlock. This way will be special long creepage distances between the armature or the magnet system on the one hand and the switching spring on the other hand, whereby the relay despite high height for low Switching capacity is suitable.

The essentially elongated anchor is more convenient Design a short, angled towards the core Bearing end section, which in a recess of the core end supported on three sides enclosing coil body flange is. If the magnet system is not excited, the armature is preferred with its movable end by a return spring biased away from the yoke leg, with a central portion on a lever line parallel to the bearing axis of the base body is pivotable, so that due to the leverage its bearing section is pressed into the bearing. This lever line is expediently by a rolling edge formed of the base body; But it would also be conceivable in the middle area of the anchor itself to provide an edge with which it could also roll on a flat surface of the base body. The return spring is advantageously by at least one integrally connected to the switching spring, by one but the contact spring carrying the movable contact is effective separate reset leg formed.

Figur 1 ein erfindungsgemäß gestaltetes Relais in Explosionsdarstellung, Figur 2 ein zusammengebautes Relais von Figur 1 im Längsschnitt,

Figur 3 eine Schaltfeder mit Federträger und Betätigunsglied in perspektivischer Darstellung,

Figur 4 eine perspektivische Ansicht des Magnetsystems von Figur 1,

Figur 5 eine perspektivische Ansicht von oben auf den Grundkörper von Figur 1,

Figur 6 eine Einzelansicht des Betätigungsgliedes,

Figur 7 eine perspektivische Ansicht auf die Unterseite des Grundkörpers mit montierter Kontaktanordnung,

Figur 8 und 9 zwei abgewandelte Ausführungsformen der Schaltfeder jeweils in einer zu Figur 3 analogen Darstellung.

The invention is explained in more detail below using exemplary embodiments with reference to the drawing.
It shows

1 shows an exploded relay according to the invention, FIG. 2 shows an assembled relay from FIG. 1 in longitudinal section,

FIG. 3 shows a switch spring with spring carrier and actuating element in a perspective view,

FIG. 4 shows a perspective view of the magnet system from FIG. 1,

FIG. 5 shows a perspective view from above of the base body from FIG. 1,

FIG. 6 shows a single view of the actuator,

FIG. 7 shows a perspective view of the underside of the base body with the contact arrangement mounted,

8 and 9 show two modified embodiments of the switching spring, each in a representation analogous to FIG. 3.

The relay shown in Figures 1 to 7 exists according to Figure 1 from a base body 1, the one on its underside Contact arrangement 2 carries with an actuator 3, and a magnet system arranged above the base body 4. The relay system is arranged in a housing that is formed by a base plate 5 and a cap 6.

The base body 1 is box-shaped made of insulating material and forms a partition 11 between the magnet system 4 and the contact arrangement 2, which only has an opening 12 for has the actuator 3. Below the partition 11 is a control room 13 formed by the side walls 14 of the Basic body is surrounded and on one side by a staged formation of the partition 11 in a contact space 13a passes with greater height. Extends in the control room A switching spring 21 over most of its length approximately parallel to the bottom of the relay by the Base plate 5 is set. The switching spring 21 is flat Leaf spring cut and forms a frame-shaped contact spring 22 with current-carrying side legs 22a, which are merge towards the free end to form a contact section 22b; on this a movable contact 29 is attached. Moreover are two actuating tabs 22c on the contact portion 22b cut free on both sides within the frame shape, such that they point towards the clamping point.

In addition, the switching spring 21 forms one piece with the contact spring 22 a fork-shaped return spring 23, which is essentially starting from the attachment end 21a of the switch spring is separated from the contact spring 22 and with two Reset legs 23a substantially parallel within the Frame shape of the contact spring 22 parallel to the side legs 22a extends (see also Figure 3). The return spring 23 forms a U-shape with its reset legs 23a, the to the outer contour of the actuator to be described 3 is adjusted.

The switching spring 21 is on a fastening end 21a Spring bracket 24 attached, which in turn via fastening tabs 24a in slots 14 on opposite Side walls 15 of the base body 1 are anchored. The mounting tabs 24a have hook-shaped contours for better Anchoring; there is also a terminal lug on the spring support 24 24b formed by a corresponding Breakthrough of the base plate 5 is guided to the outside.

The contact arrangement further comprises an NC contact carrier 25 with an NC contact 26 and one Normally open contact carrier 27 with a normally open contact 28. Both contact carriers are via fastening sections 25a and 27a in corresponding plug-in shafts 16 of the base body 1 anchored. They also each have terminal lugs 25b or 27b, which led through the base plate 5 to the outside are. The contact carriers 25 and 27 are designed and in the contact space 13a arranged so that the movable contact 29 optionally with the normally closed contact 26 and the normally open contact 28 works together.

The magnet system 4 arranged above the base body has a bobbin 41 with a winding 42, the axis is parallel to the bottom of the relay. A core yoke 43 forms in one piece a core leg 43a, which axially extends through the entire coil, and a yoke leg 43b, which is parallel to the core leg below the coil extends close to the winding to about half the coil length. An anchor 44 extends with its main part flat in extension of the yoke leg 43b, one in Cross-section recessed pole end portion 44a also Pole section 43c of the yoke leg that has a reduced cross section overlaps. A bearing end portion 44b of the armature is angled towards the free core end 43d and in a pocket 45 of a bobbin flange 41a mounted so that it rolls on the free core end 43d. The bobbin flange 41a surrounds this free core end 43d on three sides and secures it the bearing end portion 44b of the armature with retaining ribs 41b also against wandering away in the axial direction of the coil. in the the rest of this end portion 44b of the armature is passed through the restoring force of the return spring 23 in the storage pressed the core end 43d. This restoring force acts on the movable armature end 44c and pulls it away from the coil downward. This makes the armature a lever when not energized Magnet system around a rolling edge 17 on the top of the Partition 11 - in the representation of Figure 2 against Clockwise - pivoted so that the bearing end section 44b of the anchor is prestressed in the bearing. To this A separate spring is unnecessary.

The arrangement of the yoke leg 43b directly on the Winding 42 (optionally with an insulating intermediate layer) the armature 44 moves in the direction when the magnet system is excited attracted to the coil, so that the switching spring 21 via the Actuator 3 is pulled in this direction. To this The way already results below the yoke leg 43b mentioned large contact space 13a, while for the switching spring 21 the lower control room 13 below the moving armature sufficient. The actuator 3, the switching movement of the Anchor transmits has a hook portion 31 which is essentially the opening 12 of the partition perpendicular to the base plane 11 interspersed and with its hook-shaped end on one Breakthrough 44d of the armature 44 is suspended. Over the free The end of this hook part 31 is also in the pole section 43c of the pole leg 43b is provided with a recess 43e which is a complete attachment of the anchor to the yoke leg in this Area allows.

In addition, the actuator 3 has a flat foot part 32, which lies essentially in the plane of the switching spring 21 and has an M-shape in this example. The The middle leg of the M is connected to the hook part 31. Is in both outer legs of the foot part 32 a guide groove 33 is formed, in each of which a guide tab 23b of the adjacent return leg 23a engages. At the free ends of this outer leg is on the side each formed an actuating cam 34 which is below the adjacent actuating tab 22d of the contact spring and with an upward movement of the actuator 3 brings the contact spring into the closed position. By coordinating the heights of the apex on the actuating cams 34 on the one hand and the guide grooves 33 on the other can be the return position of the armature with respect to the Closing position of the normally closed contact can be set, too if the return spring and the contact spring originally are in one level. Otherwise can also by a slight bend in the return leg 23a on the one hand or the actuating tab 22c, on the other hand, a corresponding one Position can be adjusted.

To increase the insulation between the magnet system and the Contact arrangement is on the partition 11 towards the bottom an insulating collar 18 is formed, the labyrinthine between the legs of the M-shaped foot portion 32 of the actuator 3 engages and in this way long creepage distances creates.

The relay is installed in such a way that, on the one hand the magnet system according to Figure 4 is pre-assembled and on the other hand the contact arrangement 3 in the base body from the bottom is anchored here. The magnet system according to FIG. 4 is assembled with the base body according to FIG. 5, wherein Coil connector pins 46 in corresponding openings of the Basic body are inserted. Then from the bottom forth the actuator 3 by the frame-shaped switching spring inserted through and hooked into the anchor. To this The purpose of the actuator 3 is initially in an inclined position, as dashed in FIG. 2 with the reference symbol 3 ' shown, guided upwards, with the hook part 31 in the Breakthrough 12 inserted and then in the final position pivoted. Through this type of assembly of the actuator Any plastic abrasion is also without snap-in connections avoided, which could endanger the contacts. By The bottom plate 5 and the cap 6 then become the housing formed, which also seals in a known manner can be.

The function of the relay already results from that described Allocation of the individual parts. When the magnet system is excited the armature with its pole end portion 44a to the Pole portion 43c of the yoke leg 43b attracted, whereby via the actuator 3, the contact spring 22 is pulled up and the movable contact 29 with the make contact 28 is brought into contact. When the excitation is switched off pulls the return spring 23 with its return legs 23a the actuator 3 and the end 44c of the armature downwards, the anchor on the rolling edge 17 tilts like a lever and its bearing end portion 44b also without coil excitation is biased towards the yoke end 43d.

FIGS. 8 and 9 show two further possible designs the switch spring and corresponding to the actuator shown. The switching spring 121 according to FIG. 8 has a contact spring 122, which is a modification of the Contact spring 22 of Figure 3 now only a single, center has arranged leg, at the end of a contact section 122b carries the movable contact 29. The Return spring 123 is in this case by two on both sides next to the outer sides of the contact spring return legs 123a formed, each at their free ends have outwardly angled actuating lugs 123b. Corresponding the modified form of the switch spring 123 is also a modified actuator 103 is provided. This owns a U-shaped shape with two hook parts 131 as outer legs and one connecting the two hook parts Foot part 132, which extends transversely below the switching spring this extends and both a central cam section 134 for actuating the contact spring 122 and two laterally arranged guide grooves 133 for receiving the mentioned Guide lugs 123b. The two hook parts 131 extend itself up to the anchor, the anchor being natural is appropriately designed on both sides to hang to permit the hook parts 131, and also the Base body in its partition instead of the previously described central opening 12 now two outside Breakthroughs must have. The spring support 24 is as in the previous one Designed embodiment.

FIG. 9 shows a further modification compared to FIG. 8. The Switch spring 221 has a similar to switch spring 121 central contact spring 222 with a contact section 222b and a reset leg 223a formed by the outside Return spring 223, with the return leg on have a guide lug 223b at its end. The actuator 203 is similar to the actuator 103 U-shaped designed. It has two hook parts 231 and one across extending foot portion 232, in which guide grooves 233 for Recording the guide tabs 223b are formed. The actuation however, the contact spring 222 is now not carried out immediately on the middle leg 222a, but via laterally formed Actuating flaps 222c, which are approximately with the return legs 223a are aligned and each on an actuating cam 234 of the actuator 203 rest. For the Adaptation of the anchor and the base body to the changed one The same applies to actuator 8. For the rest the function results from the description of the first exemplary embodiment.

Claims (11)

1. Electromagnetic relay with an electromagnet system, consisting of a long coil (41, 42) with an axis oriented parallel to a base plane,
      a U-shaped core/yoke arrangement (43), from which a core limb (43a) axially penetrates the coil and a yoke limb (43b) extends parallel thereto under the coil over part of the coil length and forms a pole section (43c), and
      an essentially flat armature (44), which extends approximately as a projection of the yoke limb (43b) under the coil, is arranged with a bearing end section (44b) on the free end of the core (43d) and overlaps the pole section (43c) of the yoke limb (43b) with an opposite pole end section (44c) by forming a working air gap, in addition to
      a contact arrangement with at least one fixed contact (26, 28) fastened to a contact carrier (25, 27) and with a movable contact (29) carried by a spring switch (21; 121; 221) and
      with an operating element (3; 103; 203) for transmission of the movement to the spring switch (21),
      characterised in that the pole section (43c) of the yoke limb (43b) lies between the armature (44) and the coil winding (42), that the spring switch (21; 121; 221) extends essentially under the armature (44), and the contacts (26, 28, 29) are arranged under the yoke limb (43b) in the region in front of the contact space (13a) formed by the movable armature end (44c).
2. Relay according to claim 1, characterised in that the spring switch (21; 121; 221) is fastened in the region under the armature bearing (45, 44b) and extends under the armature (44) into the contact space (13a) and in that the operating element engages it in an intermediate switch space (13).
3. Relay according to claim 1 or 2, characterised in that a base body (1) out of insulating material is arranged under the magnet system (41, 42, 43, 44), carrying the spring switch (21; 121; 221) as well as the contact carrier or carriers (25, 27) and forming a dividing wall (11) between the magnet system and the contact arrangement, which comprises merely one opening (12) or openings for the operating element (3; 103; 203).
4. Relay according to claim 3, characterised in that the base body (1) comprises side walls (15) which are integrally formed downwardly and at least partly surround the switch space (13) or the contact space (13a), to which a spring carrier (24) carrying the spring switch (21) and the contact carrier or carriers (25, 27) are anchored by means of plug-in fastenings into plug shafts (14, 16).
5. Relay according to claim 4, characterised in that the dividing wall (11) forms an insulating collar (18) projecting downwards at the edge of the opening (12).
6. Relay according to claim 5, characterised in that the operating element (3) comprises a hook part (31) secured to the armature (44) and a base part (32) engaging the spring switch and which engages the insulating collar in a labyrinthine manner.
7. Relay according to one of claims 1 to 6, characterised in that the bearing end section (44b) of the armature (44) is angled in relation to the core limb (43a) and arranged in a recess (45) of a coil body flange (41a) surrounding the free end of the core limb (43d) on three sides.
8. Relay according to one of claims 1 to 7, characterised in that the armature (44) in a de-energised magnet system (41, 42, 43, 44) is biased with its pole end section (44c) by means of a restoring spring (23) away from the yoke limb (43b), whereby it lies in a pivotal manner on a lever line of the base body (1) parallel to the bearing axis, so that on the basis of the lever action its bearing section (44b) is pressed into the bearing.
9. Relay according to claim 8, characterised in that the lever line (17) is formed by an uncoiling edge of the base body (1).
10. Relay according to claim 8, characterised in that the lever line is formed by an uncoiling edge of the armature.
11. Relay according to claims 8 to 10, characterised in that the restoring spring (23; 123; 223) is formed by at least one restoring limb (23a; 123a; 223a), connected in one piece with the spring switch (21; 121; 221) and effectively separated from the spring contact (22; 122; 222).

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