EP0865060A2 - Electromagnetic relay - Google Patents

Abstract

An electromagnetic relay including a magnet assembly (3) for generating a magnetic flux, a actuating assembly (4) comprising a movable armature (13) acted on by the magnetic flux, where the two assembles (3;4) are designed so that the armature (13) is movable to and fro between at least a first and second position, and a switching assembly (5) having at least two fixed switching contacts (21,22) as well as at least one contact spring (23,24) actuated by the actuating assembly (4). The armature (13) has at least one recess (14) which is designed so that the armature (13) at least partially surrounds the magnetic assembly (3) in at least the first and/or the second position.

Description

• eine durch Anlegen einer Erregerspannung, insbesondere einer Erreger-Gleichspannung, betätigbare Magnetbaugruppe zur Erzeugung eines magnetischen Flusses,
• eine Betätigungsbaugruppe, die einen durch den magnetischen Fluß beaufschlagten, beweglichen Anker aufweist, wobei die Magnetbaugruppe und die Betätigungsbaugruppe so ausgebildet sind, daß der Anker zwischen wenigsten einer ersten und einer zweiten Lage hin- und herbewegbar ist, und
• eine Schaltbaugruppe, die wenigstens zwei feststehende Kontakte sowie wenigstens eine durch die Betätigungsbaugruppe betätigbare Kontaktfeder aufweist, die wahlweise mit jeweils einem der feststehenden Schaltkontakte elektrisch leitend miteinander verbindbar ist.

The invention relates to an electromagnetic relay, which has the following features:

• a magnet assembly which can be actuated by applying an excitation voltage, in particular an excitation direct voltage, for generating a magnetic flux,
• an actuation assembly having a movable armature acted upon by the magnetic flux, the magnet assembly and the actuation assembly being designed such that the armature can be moved back and forth between at least a first and a second position, and
• a switching assembly which has at least two fixed contacts and at least one contact spring which can be actuated by the actuation assembly and which can optionally be electrically conductively connected to one of the fixed switching contacts.

Generic electromagnetic relays are for example known from EP 0 423834 A2 and from EP 0 691 030 B1. The relays known from these publications have one Rocker anchor on that in the area between a switch assembly and a magnet assembly is arranged. When actuated the magnet assembly by applying a DC voltage to one provided in the magnet assembly is in one Core and a yoke located outside the coil Magnetic flux generated the armature depending on the polarity of the Excitation voltage so that it one of two predetermined Occupies layers. The anchor actuates a movable one Contact spring carrying switch contacts, the provided via fixed switching contacts predetermined contact pins on the bottom of the relay electrically conductive with each other connects.

A similar electromagnetic relay is from the EP 0 293 199 A2 known. In those known from EP 0 293 199 A2 Relays enter the contact pins of the switch module however on the side of the relay housing on which the magnet assembly is located.

Finally, from WO 94/13 002 and from EP 0 640 243 B1 known electromagnetic relays in which the armature above the magnet assembly and the switch assembly is arranged, the movement of the armature by provided sliding links on the switch module is transmitted.

In the above relays, it is particularly disadvantageous that these have a large overall height, which means their use in circuits for applications with limited space.

It is therefore an object of the invention to provide a generic electrical Relay provide that only a small space claimed.

According to the invention, this object is achieved in that the anchor has at least one recess, which is formed in this way is that the armature in at least the magnet assembly of the first and / or second layer at least partially.

The invention is based on the basic idea that at least partial areas of the armature in the plane of the magnet assembly located so that only a small portion of the armature must be arranged above the magnet assembly. Thereby the anchor takes up little space above the magnet assembly, so that there is a particularly space-saving electromagnetic Relay can be trained.

The armature is preferably designed such that it is the magnet assembly not only in certain positions, but in every position at least partially included. This is particularly easy thereby achieve that the recess or the recesses are each designed as a breakthrough.

When the anchor is in the top view the shape of a rectangle has, two in the longitudinal direction of the rectangle side by side rectangular recesses are provided, then the result is a particularly stable and space-saving Anchor. Such an anchor has the shape of the top view Number eight (8). Deviating from this configuration, the Anchor can also be designed so that it is H-shaped in plan view is.

This is the case with the two above configurations of the armature a central web is provided between the two cutouts, the advantageously a crowned cross section Surface. A trained as above Anchor can be directly and without additional storage elements on the Magnet system or another component of the invention electromagnetic relays are stored.

A particularly inventive can save space Train the relay with an anchor that is in the view from the Side has cranked longitudinal ends. This is about it also an increase in the range of motion of the invention Anchor ensured. This makes it reliable Achieve circuits in the relays according to the invention, these only take up a small amount of space.

The inventive idea can be achieved in a particularly advantageous manner apply to relays where the anchor acts as a rocker anchor is trained. In particular, the above Configurations in a rocker anchor on particularly simple Way to be realized.

In one embodiment of the invention, the magnet assembly designed as a polar magnet system. This allows you to a particularly simple way a polarized electromagnetic Form relay, the switching state of the polarity depends on the excitation voltage applied to the magnet assembly.

The polar magnet system can have a magnetic circuit with at least a coil with a coil core, with two each on one End of the coil core arranged pole pieces and with a parallel to the axis of the coil and between the pole pieces arranged, three-pole magnets. Instead of of the coil core with the two pole pieces, it is also possible to provide a U-shaped or an L-shaped yoke as the coil core.

• zwei Spulen mit axial fluchtend hintereinander angeordneten Kernabschnitten,
• zwei je an einem freien Ende der Kernabschnitte angeordnete Polschuhe,
• einen zweipoligen Dauermagneten, der zwischen beiden Spulen senkrecht zu deren Achse angeordnet ist, und zwar derart, daß ein Pol des Magneten mit den beiden Kernabschnitten gekoppelt ist und daß der andere Pol des Magneten mit einem auf ihm gelagerten Mitelabschnitt eines Wippankers gekoppelt ist, dessen Enden mit den Polschuhen jeweils Arbeitsluftspalte bilden.

In deviation from this, the polarized magnet system can also have a magnetic circuit with the following features:

• two coils with axially aligned core sections,
• two pole shoes each arranged at a free end of the core sections,
• a two-pole permanent magnet, which is arranged between the two coils perpendicular to the axis thereof, in such a way that one pole of the magnet is coupled to the two core sections and that the other pole of the magnet is coupled to a center section of a rocker armature mounted thereon, the ends of which form working air gaps with the pole pieces.

The above two alternatives to training the poled Magnet systems enable the production of a special one reliable electromagnetic relay according to the invention.

Deviating from the above embodiments of the invention The magnetic assembly can use electromagnetic relays also be designed as an unpoled magnet system. A such a design is usually used for monostable electromagnetic relay selected, the unpoled magnet system a magnetic circuit with at least one coil and provided with a coil core designed as a U-shaped yoke is. The U-shaped yoke can be formed in one piece or deviating from a rod-shaped coil core and from an L-shaped one located on the outside of the coil The yoke must be composed, with the coil core and yoke being magnetic are connected in series. The is advantageous legs of the yoke arranged on the outside of the coil shorter than that arranged on the inside of the coil Leg. This results in a particularly reliable Actuation of the electromagnetic according to the invention Relay. The longer leg of the Yoke the spool completely, with the protruding from the spool A pole piece is additionally provided at the end of the leg is. This favors what is necessary to actuate the armature magnetic flux.

In a further embodiment of the invention, the actuation assembly at least one in particular made of insulating material manufactured sliding link on one end or both Ends of the armature each with at least one contact spring of the anchor movably connects. The electromagnetic trained in this way Relay allows in a particularly simple way a spatial distance and particularly good insulation to be provided between the switch assembly and the magnet assembly.

In the embodiments of the invention explained so far electromagnetic relay is usually the embodiment with polar magnet system and rocker armature for it used to provide a bistable electromagnetic relay while the embodiment with a non-polar magnet system to produce a monostable electromagnetic Relay is used. Provided certain mechanical Additional elements, it is also possible that with the poled Magnetic system provided electromagnetic relays monostable to perform, for example, by different design the working air gap on both sides of the anchor or by different adjustment of the (three-pole) permanent magnet.

Deviating from this, it is also possible to at least anchor the anchor a direction of movement with one by a return spring to generate generated restoring force. According to the idea of the invention the anchor can also over parts of the actuator operated by the return spring.

In a further development of the switch assembly, one is the contact spring or the spring assembly containing the contact springs is provided, who continue to make one from insulating material and has a central web that can be acted upon by the anchor. A spring assembly designed in this way allows one particularly good insulation of the contact springs and thus the reach switching load from the magnet system. This gives a particularly reliable working electromagnetic Relay.

The spring assembly can be particularly simple Manufacture in such a way that the central web as a plastic extrusion the first as a circuit board from a thin sheet stamped contact spring or the contact springs is.

The electromagnetic relay according to the invention also has a relay stiffening and the assemblies of the relay load-bearing support assembly, which also one for receiving have in particular the magnetic assembly certain basic body can. The base body is advantageously made of made of an insulating material and has an H-shaped Cross section and closed side surfaces and End faces on. This design of the support assembly can an otherwise usual cap for covering the modules of the relay omitted. The H-shaped profile of the base body gives the relay has a high longitudinal rigidity. Through training the base body is made of an insulating material the reliability and operational safety of the invention electromagnetic relay increased.

Furthermore, it is provided according to the invention that the base body Pockets for receiving power supply contacts the magnet assembly. This makes it possible electromagnetic relays according to the invention in a particularly simple manner Assemble way. Guides can also be found in the basic body be provided for receiving the actuator assembly. Such guides can then in particular the connecting links between the armature and the spring assembly, whereby a particularly reliable operation of the Spring assembly is guaranteed.

Figur 1

zeigt einen Längsschnitt durch ein erfindungsgemäßes, polarisiertes elektromagnetisches Relais,

Figur 2

zeigt das Relais aus Figur 1 in einer perspektivischen Darstellung mit teilweise geschnitten dargestelltem Gehäuse,

Figur 3

zeigt das Relais aus den Figuren 1 und 2 in explosionsartig auseinandergezogener Darstellung seiner Einzelteile,

Figur 4

zeigt einen Längsschnitt durch ein weiteres erfindungsgemäßes, neutrales elektromagnetisches Relais und

Figur 5

zeigt das Magnetsystem des Relais von Figur 4 in perspektivischer, teilweise geschnittener Darstellung.

Finally, it is also provided that the support assembly has a base assembly which can be connected to the base body and is intended for receiving at least a part of the contact assembly. With this configuration, the relay can be installed in a particularly simple manner. The invention is illustrated in more detail in the drawing using two exemplary embodiments.

Figure 1

shows a longitudinal section through a polarized electromagnetic relay according to the invention,

Figure 2

1 shows the relay from FIG. 1 in a perspective view with the housing shown partially in section,

Figure 3

shows the relay of Figures 1 and 2 in an exploded exploded view of its parts,

Figure 4

shows a longitudinal section through a further inventive neutral electromagnetic relay and

Figure 5

shows the magnet system of the relay of Figure 4 in perspective, partially sectioned representation.

Figures 1 to 3 show a longitudinal section through an inventive electromagnetic relay 1. The relay 1 is divided into a support assembly 2, which at the same time Takes over the function of a housing, in a magnet assembly 3, into an actuation assembly 4 and into one in the area of the underside of the electromagnetic relay 1 located contact assembly 5. The magnet assembly 3 is designed so that the contact assembly 5 via the actuation assembly 4th can be actuated.

The central element of the magnet assembly 3 is that by two electrical connections 37 and 38 with an excitation voltage optionally actable in one direction or the other Coil 6, which is applied to a bobbin 7 Has coil winding 8. The bobbin 7 is as best seen in Figure 1, in the direction of the longitudinal axis the coil 6 is provided with a coil tube 9 in which a Coil core 10 is added. On both sides of the coil core 10 pole shoes 11 are provided, with between the free ends the pole pieces 11 inserted a three-pole permanent magnet 12 is. The three-pole permanent magnet 12 is designed so that it has an N pole in the region of its ends, while an S pole is provided in its central region. How The pole shoes 11 can be seen in particular in FIG. 2 graduated in the area of their upper ends. In this way, stepped pole faces are created on both sides 11a, between which a longer middle section 11b follows protrudes above.

Depending on the direction of the magnetic generated in the coil core 10 Flux actuates the magnet assembly 3, the actuation assembly 4 in different ways.

For this purpose, the actuation assembly 4 has one on the top the coil 6 arranged armature 13, which is particularly good in the perspective representations in Figures 2 and 3 see is. The anchor 13 has the shape of a in plan view lying number 8 and is based on the rocker principle designed. The anchor 13 is essentially rectangular Shape with beveled corners and is made of a thin ferromagnetic Made of sheet metal. Two are essential rectangular recesses 14 are introduced in the armature 13, the lie side by side in the longitudinal direction of the armature 13. Between the recesses 14, a central web 15 is formed which in Has cross-sectionally spherical surfaces 15a and 15b, as best seen in Figure 1. Furthermore are in the area the ends of the armature 13 at the end connecting webs 16 educated. The ends are in the area of the connecting webs 16 the armature 13 is cranked relative to its central region 13a, while the central region 13a essentially in longitudinal section has an arcuate shape.

The anchor 13 lies with a lower surface 15a of the central web 15 as a rotary coupling surface in the central area of the three-pole permanent magnet 12, as best shown in Figure 1 see is.

As can be seen particularly well in FIG. 2, the sides protrude Areas of the armature 13 in the plane of the three-pole permanent magnet 12 in. When the armature seesaws 13 around the central web 15 on the three-pole permanent magnet 12 the connecting webs 16 move in the region of the pole shoes 11 up and down. This ensures that in an end position of the anchor 13 the top of the then straight up projecting connecting web 16 does not over the top 15b of the Mittelsteges 15 protrudes. In connection with training the magnet assembly 3, according to which the pole faces 11a of the pole pieces 11 laterally offset next to the coupling surfaces for three-pole permanent magnet 12, there is a particularly space-saving design of magnet assembly 3 and Actuator assembly 4, because the relay 1 is only a small one Height claimed. The anchor forms on both sides of its recesses 14 the working air column with the offset Pole surfaces 11a, while the respective middle section 11b of the Pole shoe 11 dips into the recess 14 of the armature and so an additional river crossing like a reverse Diving anchor principle causes.

The actuation assembly 4 also has two sliding members 17, which in the region of the ends of the coil 6 are arranged that the tops of the sliding members 17 each can be acted upon by the connecting webs 16 of the armature 13 are. The sliding members 17 are flat rectangular Insulated sections formed as best in Figure 3 can be seen.

The switching assembly is connected to the actuation assembly 4 5, which essentially consists of a spring assembly 18 and consists of fixed contacts 19 and 20, respectively Contact pins 21 and 22 are connected. The spring assembly 18 has two separate, parallel ones Leaf springs 23 and 24, which are welded at the ends Wear switch contacts 25. The leaf springs 23 and 24 are prefabricated from a common circuit board and with insulating Material overmolded, so that there is an insulating between them Mittelsteg 26 trained. The leaf springs 23 and 24 have middle connection tabs, which are horizontal, and the have fastening tabs 27 bent down at their ends, which are connected to corresponding center contact pins 29 are.

The central web 26 is at each end as an actuating head 30 molded with the underside of the sliding members 17 in Contact is there. The magnet assembly 3, the actuation assembly 4 and the switching assembly 5 are within the as Housing trained support assembly 2 arranged. More central Part of the support assembly 2 is the base body 31, the in a cross section transverse to the plane of that shown in Figure 1 Representation has an H-shaped shape. The base body 31 is made of insulating material and has an inner tub 32 to accommodate the magnet assembly 3. Here are on an end face of the base body 31 on the inside between the inner tub 32 and the end guides 33 for the sliding members 17 are provided. The inner tub 32 is like this formed that the base body 31 has a high longitudinal rigidity having. The center contact pins 29 are in for this provided pockets in the bottom of the inner tub 32 plugged in. For the passage of the contact pins 37, 38 of the coil 6 are special openings in the inner tub 32 provided.

The base body 31 is covered by a cover plate 34 closed, the paragraphs 35 formed on its underside between which the central web 15 of the armature 13th is guided with its spherical top 15b. Finally the support assembly 2 still has a base 36 which the Base body 31 closes down and the contact pins 21 and 22 and the associated fixed contacts 19 and 20 carries.

For assembly, the coil 6 is inserted into the base body 31 from above used. Then the pole pieces 11 are on the coil core 10 placed and the three-pole permanent magnet 12 mounted. Subsequently the components of the magnet assembly 3 through a potting compound glued together. Then the sliding links 17 inserted into the guides 33 provided for this purpose. The armature 13 is then on the magnetic assembly 3rd put on. Finally, the base body 31 by the Cover plate 34 closed at the top.

In the base body 31 then turned over, the spring assembly 18 used, the connecting tab 27 of the Leaf springs 23 and 24 by resistance or laser welding on the contact pins corresponding to the center connections 28, 29 are attached. The spring assembly 18 is at rest the armature 13 attached to the center terminals 29, whereby a monostable with flexible storage Preload of the spring assembly 18 can be reached.

The base 36 is then pressed into the base body 31 so far that until with regard to the fixed contacts 19 and 20 sets a desired contact lift. This will the armature 13 brought into an end position, the contact between Switch contacts 25 and fixed contacts 19 monitored and the base 36 in about the desired overstroke pushed the base body 31. After the anchor has been flipped 13 on the other side, the desired one is also on this Contact overrun set. The base 36 is in this view not shown displacement ribs in the base body 31 held. Then the base 36 with the base body 31 glued and the relay 1 sealed.

The contact pins 21, 22, 29, 37 and 38 can be used for an SMD variant of the relay 1 and transformed to the corresponding Length can be cut off.

Figures 4 and 5 show a neutral or non-polarized Embodiment of an electromechanical according to the invention Relay 40, which is a support assembly 41, a magnet assembly 42, an actuator assembly 43 and one Switch assembly 44 has.

The support assembly 41 is identical to the support assembly 2 from Figures 1 to 3, so that on their detailed Description is waived. The same components are given the same reference numbers. The same applies to the actuator assembly 43, which is identical to the actuator assembly 4 from Figures 1 to 3, and for Switch assembly 44, which is identical to the switch assembly 5 from Figures 1 to 3 corresponds.

The neutral relay 40 differs from relay 1 essentially in that an unpoled magnet system without permanent magnets is present. For this purpose, the magnet assembly 42 has the coil 6, which has a bobbin 7 with a provided thereon Has coil winding 8. In the coil tube 9 is a U-shaped Introduced core yoke 45, the shorter yoke leg 46 on the outside of the coil 6. On the end section of the the shorter yoke leg 46 is the central web 15 of the armature 13 Rollable arranged above the center of the spool. The longer core leg 47 of the yoke 45 is designed as a core so that it when fully inserted into the bobbin 7 protrudes beyond an end face of the coil 6. On about the End of the coil 6 protruding end of the longer Leg 47 is followed by a pole piece 48, which is vertical runs to the axis of the coil 6.

The assembly of the relay 40 largely corresponds to that of the previous one described relay 1, of course the neutral magnet system without permanent magnet and with just one pole shoe Modifications.

The function of the neutral system results from that in the Figures 4 and 5 shown structure. The rocker armature 13 acts in this case only with his right one in the illustration Anchor end together with the single pole piece 48, which like that Pole shoes 11 mutually offset pole faces 48a for formation the working air gap has. The middle section 48b dips into a recess 14 of the Anchor 13 a while the opposite anchor end only has an actuating web 16, but no working air gap forms. On this side a part of the yoke leg appears 46 in the recess 14 of the armature, which in the Width compared to the core leg 47 is reduced.

Since it is a neutral system, the anchor must be biased into its rest position by spring force. This can happen, for example, that the contact springs are biased unevenly, causing the sliding member 17th on the right side of Figure 4 the anchor from the pole face 48a and the contacts on the left anchor end keeps the left side closed when idle. When excited of the magnet system, the armature is attached with its right end the pole face 48a attracted, whereby the contacts on the closed on the right side of Figure 4 and those on the left side. You can use the preload at adjust or reinforce the assembly by fastening tabs 27 are welded to their connecting pin 29, while the contacts 19, 25 on the left in FIG. 4 are closed being held. If the bias of the contact springs is not sufficient to achieve the monostable bias an additional spring to generate the required restoring force can be used for the anchor.

Claims (25)

Electromagnetic relay that has the following features: a magnetic assembly (3, 42) which can be actuated by applying an excitation voltage to generate a magnetic flux, an actuation assembly (4, 43) having a movable armature (13) acted upon by the magnetic flux, the magnet assembly (3, 42) and the actuation assembly (4, 43) being designed such that the armature (13) between at least a first and a second layer can be moved back and forth, and a switching assembly (5, 44) which has at least two fixed switching contacts (21, 22) and at least one contact spring (23, 24) which can be actuated by the actuating assembly (4, 43) and which optionally has one of the fixed switching contacts (21, 22 ) can be connected in an electrically conductive manner, characterized in that the armature (13) has at least one recess (14) which is designed in such a way that the armature (13) at least partially surrounds the magnet assembly (3, 42) in at least the first and / or the second position. Electromagnetic relay according to claim 1, characterized in that the armature (13) is designed such that he the magnetic assembly (3, 42) at least in any position partially included. Electromagnetic relay according to claim 1 or claim 2, characterized in that the recess or Recesses (14) are each designed as an opening or are. Electromagnetic relay according to claim 3, characterized in that the anchor (13) in plan view Has the shape of a rectangle, two in the longitudinal direction of the rectangle next to each other, rectangular Recesses (14) are provided. (the shape of an 8). Electromagnetic relay according to claim 3, characterized in that the anchor (13) is H-shaped in plan view is trained. Electromagnetic relay according to claim 4 or claim 5, characterized in that the armature (13) in the area a central web between the two recesses (14) (15), the at least one crowned in cross section has trained surface. Electromagnetic relay according to one of the preceding Claims, characterized in that the armature (13) in the view has cranked longitudinal ends from the side. Electromagnetic relay according to one of the preceding Claims, characterized in that the anchor as Rocker anchor (13) is formed. Electromagnetic relay according to one of the preceding Claims, characterized in that the magnet assembly is designed as a polar magnet system (3). Electromagnetic relay according to claim 9, characterized in that the polar magnet system (3) a magnetic circuit with at least one coil (6) with a coil core (10), with two at each end of the coil core (10) arranged pole pieces (11) and with a parallel to the axis of the coil (6) and between the pole pieces (11) arranged, three-pole magnet (12). Electromagnetic relay according to claim 9, characterized in that the polar magnet system has a magnetic circuit with the following features: two coils with axially aligned core sections, two pole shoes each arranged at a free end of the core sections, a two-pole permanent magnet, which is arranged between the two coils perpendicular to their axis, in such a way that one pole of the magnet is coupled to the two core sections and that the other pole of the magnet is coupled to a center section of a rocker armature mounted thereon, the end of which form the working shoes of the pole shoes. Electromagnetic relay according to one of claims 1 to 8, characterized in that the magnet assembly is designed as an unpoled magnet system (42). Electromagnetic relay according to claim 12, characterized in that the unpoled magnet system (42) one Magnetic circuit with at least one coil (6) and with one has a coil core designed as a U-shaped yoke (45). Electromagnetic relay according to claim 13, characterized in that the U-shaped yoke from a rod-shaped Coil core and one on the outside of the Coil arranged, L-shaped yoke is assembled, where coil core and yoke are magnetically connected in series are. Electromagnetic relay according to claim 13 or claim 14, characterized in that on the outside the coil (6) arranged leg (46) of the Yokes (45) shorter than that on the inside of the coil (6) arranged leg (47) is formed. Electromagnetic relay according to one of the preceding Claims, characterized in that the actuating assembly (4, 43) at least one in particular made of insulating Material made sliding member (17), one end (16) or each of the two ends of the Armature (13), each with at least one contact spring (23, 24) movably connects. Electromagnetic relay according to one of the preceding Claims, characterized in that the actuating assembly has at least one limiting member which is designed so that the movement of the armature in at least a direction of movement can be limited. Electromagnetic relay according to one of the preceding Claims, characterized in that the actuating assembly has at least one return spring which is arranged so that the anchor in at least one direction of movement can be loaded with a restoring force is. Electromagnetic relay according to one of the preceding Claims, characterized in that the switching assembly (5, 44) at least one the contact spring or the Has spring assembly containing contact springs (23, 24), wherein the spring assembly continues to isolate one Material produced and acted upon by the anchor (13) Has central web (26). Electromagnetic relay according to claim 19, characterized in that the central web (26) as a plastic coating the contact spring or the contact springs (23, 24) is formed. Electromagnetic relay according to one of the preceding Claims, characterized in that the relay stiffening and supporting the assemblies of the relay Support assembly (2, 41) is provided, one for receiving in particular the magnetic assembly (3, 42) Has base body (31). Electromagnetic relay according to claim 21, characterized in that the base body (31) from an insulating Material is made and an H-shaped Cross section as well as closed side faces and end faces having Electromagnetic relay according to claim 21 or claim 22, characterized in that the base body (31) Pockets for receiving power supply contacts (37, 38) of the magnet assembly (3, 42). Electromagnetic relay according to one of claims 21 to 23, characterized in that the base body (31) Guides (33) for receiving the actuation assembly (4, 43). Electromagnetic relay according to one of claims 21 to 24, characterized in that the support assembly (2, 41) connectable to the base body (31) Has base assembly (36) for receiving at least a part of the switch assembly (5, 44) is determined.

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