DE102012015037B4 - electronics module - Google Patents

Abstract

Electronic module, in particular a relay base, for mounting on a mounting rail, with a housing (2), at least two conductor connection elements (3, 4), at least one electronic component arranged in the housing (2) or which can be plugged onto the housing (2), in particular a relay ( 5), and a first bridging connection (6), the bridging connection (6) being electrically conductively connected to an associated conductor connection element (3) and being arranged on the same side of the mounting rail (T) as the conductor connection elements (3, 4) and being for the electrical Connection of the bridging connection (6) to a bridging connection (6') of an adjacent electronic module (1'), a plug (7) of a plug-in bridge (8) can be inserted into the bridging connection (6), characterized in that a second bridging connection (10) is provided is, in which a plug (7 ') of a second plug-in bridge (8') can be inserted, the second bridging connection (10) being electrically conductive with the first bridging gs connection (6), and that the two bridging connections (6, 10) are next to one another on an end face (11) of the housing (2) running in the longitudinal direction (L) of the mounting rail (T) or in the direction in which the electronic modules (1, 1') are arranged are arranged and each have a predetermined distance (x1, x2) from the adjacent outer edge (12, 13) of the housing (2).

Description

The invention relates to an electronic module, in particular a relay base, for mounting on a mounting rail, with a housing, at least two conductor connection elements, at least one electronic component arranged in the housing or which can be plugged onto the housing, in particular a relay, and a first bridging connection, the bridging connection being an electrical is conductively connected to an associated conductor connection element and is arranged on the same side of the mounting rail as the conductor connection elements, and for the electrical connection of this bridging connection to a bridging connection of an adjacent electronic module, a plug of a jumper can be inserted into the bridging connection.

Electronic modules and electronic devices to be placed on a mounting rail have been known for many years and are used in various embodiments and for various applications. Similar to electrical terminal blocks, which are usually also snapped onto mounting rails, the electronic modules in question have at least two conductor connection elements, screw terminals or spring-cage terminals being used predominantly as conductor connection elements. In addition, torsion spring terminals have also been increasingly used for several years, which are also referred to as direct connection terminals, since they enable the direct connection of a rigid conductor or a conductor provided with a ferrule without the terminal point - as with tension spring terminals - having to be opened beforehand.

In contrast to classic electrical terminal blocks, which are designed as pure feed-through terminals, so that the at least two conductor connection elements are only electrically connected to one another via a busbar, the electronic modules in question also have an electronic unit that is often designed to be pluggable, so that they which then functions as a connection base electronic module can be plugged. The electronic component that can be plugged on can in particular be a relay, so that the electronic module represents a relay base.

the DE 10 2004 043 467 A1 and the DE 10 2004 043 466 A1 disclose in each case a power supply module with a housing which has connection terminals in its interior which are electrically connected to first and second plug-in connections. An adapted jumper plug is provided for electrical contacting of the plug-in connections with a multi-phase power distribution system, by means of which an electrical plug-in connection can be established between a power feed module and a plurality of busbars, which are accommodated in a carrier arranged adjacent on a mounting rail. In the case of the known power feed module, the electrical connection between the conductor connection elements and the first bridging connections runs transversely through the central region of the housing, namely from one side of the mounting rail to the other.

the DE 10 2007 028 643 A1 discloses a DIN rail mounted device that can be mounted on a mounting rail, the front of which is divided into three sections, the middle section of which protrudes from the two adjacent device shoulders. In the case of the known modular installation devices, conductor connection elements are arranged on one device shoulder, while a bus line section is guided in the other device shoulder. To connect the bus conductor sections of individual DIN rail mounted devices arranged next to one another, plug connectors are provided which can be plugged into corresponding receptacles in the device shoulders of adjacent DIN rail mounted devices.

the DE 299 08 612 U1 discloses a terminal block for accommodating an electronic component, in particular a relay, with a clamping body that can be snapped onto a mounting rail and has a recess into which the relay is inserted and can be fastened with the aid of a swivel bracket. So that electronic components or relays with different dimensions can also be securely latched onto this terminal block, it is proposed that the pivot bracket have at least two latching means with which relay components with different dimensions can be locked.

Relay sockets are typically connected by individual lines, which leads to a relatively high amount of wiring if - as is the rule in practice in mechanical and plant engineering - a plurality of relays have to be electrically connected via the individual relay sockets. In order to reduce the wiring effort, the connection elements of the same potential are electrically connected to one another, particularly in the case of relay bases or electronic modules mounted adjacent to one another on a mounting rail. In the simplest case, this electrical connection of individual conductor connection elements could be implemented by means of individually assembled individual lines, which, however, would not significantly reduce the wiring effort.

In practice, therefore, plug-in bridges are often used that have at least two plugs that can each be plugged into a bridging connection of two adjacent electronic modules. Such jumpers can in this case also have more than two plugs, so that a corresponding plurality of electronic modules can be electrically connected to one another with them. Such jumpers, which are often referred to as cross-connectors are, for example, from DE 195 42 628 C1 known, the cross-connector disclosed in this publication having the special feature that it consists of at least two double-layered cross-connector pieces which can be connected to one another, so that the cross-connector can be easily lengthened.

The disadvantage of plug-in bridges is that they have a fixed grid width that is predetermined by the distance between the plugs, so that plug-in bridges can only be used if the electronic modules also have a corresponding grid width. Since, for example, relay sockets often have a width of 30 mm, cross-connectors provided for use with such relay sockets, regardless of whether they have two or more plugs, must also have a pitch of 30 mm. This means that different plug-in bridges with correspondingly different grid widths are required to bridge relay bases with different overall widths.

An alternative bridging concept consists in the use of pitch-independent or pitchless cross-connectors, such as those from the DE 296 11 543 U1 are known. Although the use of such cross-connectors without division and the corresponding design of the relay sockets with a corresponding cross-connector slot makes it possible to bridge relay sockets with one another that have different widths, the maximum number of relay sockets that can be bridged in this way depends on the overall width of the socket and the length of the cross connector. On the one hand, this limits the maximum number of relay sockets to be bridged, and on the other hand the length of the cross-connector may have to be shortened individually if the total width of the relay socket to be bridged is less than the length of the cross-connector.

The present invention is therefore based on the object of avoiding the aforementioned disadvantages as far as possible and of specifying a bridging concept or an electronic module with which simple bridging of electronic modules with different overall widths is also possible.

This object is achieved in the electronics module described at the beginning with the features of claim 1 in that a second bridging connection is provided, into which a plug of a second jumper can be inserted, the second bridging connection being electrically conductively connected to the first bridging connection. The two bridging connections are arranged next to one another on an end face of the housing running in the longitudinal direction of the mounting rail or in the direction in which the electronic modules are arranged, with the two bridging connections each having a predetermined distance from the adjacent outer edge of the housing. The inventive arrangement of a second bridging connection, which is electrically conductively connected to the first bridging connection, and the positioning of the two bridging connections at a predetermined distance from the respective adjacent outer edge of the housing, the bridging of two adjacent electronic modules can be implemented in that the two connectors plugged into the two adjacent bridging connections of the two neighboring electronic modules using a jumper.

In the case of several relay bases arranged next to one another, the arrangement of the potentials - positive pole and negative pole - always alternates in the relay bases, with a bridging connection always being electrically conductively connected to only one potential. This means that the grid width of the jumper must correspond to the overall width of the relay base, since the jumper with its two plugs always has to jump over a bridging connection. Since the two plugs of a jumper are plugged into the two adjacent bridging connections of two adjacent electronic modules in the electronic module according to the invention, the distance between two bridging connections or two poles in the housing of an electronic module has no influence on the required grid width of the jumper, so that even for electronic modules with different widths, the same type of jumper with the same grid width can always be used.

This has the advantage for the user that relay bases of different widths can be bridged with one another, although only one type of jumper is required for this. In addition, the number of electronic modules that can be bridged with one another is not limited; another electronic module can always be bridged with another jumper. Finally, it is also not necessary to shorten the jumper depending on the number or the overall width of the electronic modules or to assemble it in any other way.

According to an advantageous embodiment of the electronic module according to the invention, the distance between the two bridging connections is from the respectively adjacent outer edge of the housing the same size, ie both bridging connections are equally spaced from the respective adjacent outer edge. The required latching width of a jumper then corresponds to twice the distance between a bridging connection and the adjacent outer edge of the housing and is therefore—as already explained before—independent of the overall width of the housing.

The electrically conductive connection between the one conductor connection element and the first bridging connection as well as between the two bridging connections can preferably be realized by a metal stamped and bent part. As a result, the electrical connection can be made particularly easily. In this case, the bridging connections are preferably formed as part of the metal stamped and bent part. If the individual plugs of the jumper each have at least two contact legs, so that the plugs themselves are resilient, the bridging connections can simply be realized as openings punched out of the stamped bent part, into which the plugs of the jumper are inserted.

If the preferred embodiment of the electronic module is a relay base with a relay plugged onto the housing as the electronic component, a relay retaining bracket for mechanically fixing the plugged-on relay is preferably pivotably attached to the housing. A web or a projection can preferably also be formed on the relay retaining bracket in such a way that an inserted relay can be ejected from the relay socket by pivoting the relay retaining bracket. In addition to its holding and securing function, the relay retaining bracket also has an ejection function. In addition, the relay holding bracket preferably has an identification surface on which a corresponding identification plate can be attached or snapped in place, so that the relay socket can be identified easily and in a clearly visible manner.

• 1 eine schematische Darstellung eines Brückungskonzepts bei Elektronikmodulen gemäß dem Stand der Technik,
• 2 eine schematische Darstellung des Brückungskonzepts bei erfindungsgemäßen Elektronikmodulen,
• 3 eine perspektivische Darstellung zweier benachbarter, erfindungsgemäßer Elektronikmodule,
• 4 die beiden Elektronikmodule gemäß 3 in der Seitenansicht, und
• 5 ein Ausführungsbeispiel einer Steckbrücke zur Verwendung bei erfindungsgemäßen Elektronikmodulen.

In detail, there are now a large number of possibilities for designing and developing the electronic module according to the invention. For this purpose, reference is made both to the patent claims subordinate to patent claim 1 and to the following description with reference to the figures. Show in the drawing

• 1 a schematic representation of a bridging concept for electronic modules according to the prior art,
• 2 a schematic representation of the bridging concept in electronic modules according to the invention,
• 3 a perspective view of two adjacent electronic modules according to the invention,
• 4 the two electronic modules according to 3 in side view, and
• 5 an embodiment of a jumper for use in electronic modules according to the invention.

Based on 1 and 2 , which each schematically show three electronic modules 1, 1', 1" arranged next to one another, the difference between the bridging concept according to the prior art ( 1 ) and the bridging concept according to the invention ( 2 ) are explained. The electronic modules 1, 1', 1" in the 1 and 2 are shown only schematically, each have a housing 2, in which two conductor connection elements 3, 4 are arranged. Not shown in the 1 and 2 that on or in the housing 2 of the electronic modules 1, 1′, 1″ one more electronic component can be plugged in or on.

In the 1 The electronic modules 1, 1' and 1" shown each have two bridging connections 6, 10, with the first bridging connection 6 being electrically conductively connected to the first conductor connection element 3 and the second bridging connection 10 being electrically conductively connected to the second conductor connection element 4. For connecting two identical potentials of two electronic modules 1, 1' in the electronic modules 1, 1', 1" known from the prior art, the first plug 7 of a plug-in jumper 8 must be plugged into the first bridging connection 6 of the first electronic module 1 and the second plug 9 of the plug-in bridge 8 into the first bridging connection 6 'The second electronic module 1' are inserted.

How out 1 As can be seen, the second bridging connection 10 of the first electronic module 1 must be jumped over by the jumper 8 so that the bridging connections 6, 6', which carry the same potential, are contacted by the jumper 8 or the two plugs 7, 9. This inevitably means that the grid width of the jumper 8, ie the distance between the two plugs 7, 9, must correspond to the overall width of the electronic module 1. If the electronic modules 1, 1′, 1″ have different overall widths, as is the case in the schematic representation according to FIGS 1 and 2 If this is the case, in the electronic modules 1, 1′, 1″ known from the prior art, this means that two jumpers 8, 8′ are required to bridge the electronic modules 1, 1′, 1″, each of which has a different one have grid width. Since the second electronic module 1' has a smaller overall width than the first electronic module 1, the second jumper 8' must have a corresponding have a smaller grid width than the first jumper 8.

While in the known electronic modules 1, 1 ', 1' accordingly 1 the two bridging connections 6, 10 are each electrically conductively connected to a conductor connection element 3, 4, is the same for the electronic modules 1, 1′, 1″ according to the invention 2 in each case the second bridging connection 10 is electrically conductively connected to the first bridging connection 6 . The two bridging connections 6, 10, which are arranged side by side on the end face 11 of the housing 2 running in the longitudinal direction of the mounting rail, are always at a predetermined distance x ₁ or x ₂ from the respective adjacent outer edge 12 or 13 of the housing 2, while the spacing of the bridging connections 6, 10 from one another is different depending on the overall width of the electronic modules 1, 1', 1".

Adjacent electronic modules 1, 1', 1" can then be bridged by inserting a plug 7 of a jumper 8 in the second bridging connection 10 of the first electronic module 1 and the second plug 9 of the jumper 8 in the adjacent first bridging connection 6' of the adjacent second Electronic module 1' is plugged in. The grid width of the jumper 8 no longer depends on the overall width of the electronic modules 1, 1', 1" but only on the distance x ₁ of the first bridging connection 6 from the adjacent outer edge 12 of the housing 2 and on the distance x ₂ of the second bridging connection 10 from the adjacent edge 13 of the housing 2. If the distance x ₁ of the first bridging connection 6 from the first edge 12 corresponds to the distance x ₂ of the second bridging connection 10 from the second, opposite edge 13 of the housing, the grid width of the jumper 8 must be equal to twice the distance x ₁ , x ₂ provided the two electronic modules 1, 1' to be bridged are arranged directly adjacent to one another. According to the illustration 2 it can be seen that in the bridging concept according to the invention for bridging three electronic modules 1, 1', 1" with different overall widths, two plug-in bridges 8, 8' can be used, which have the same grid width. The user therefore always requires electronic modules 1 with different overall widths only one jumper type with one grid width.

the 3 and 4 each show two relay sockets 1, 1' as preferred expression examples of the electronic modules according to the invention. A relay 5, 5' is plugged onto the housing 2 of the two relay sockets 1, 1' and can be electrically connected via conductor connection elements 3, 4 which are arranged in the relay sockets 1, 1'. The in the 3 and 4 The relay bases 1 , 1 ′ shown also each have a relay retaining bracket 14 for mechanically fixing a plugged-on relay 5 , the relay retaining brackets 14 being pivotably mounted on the housing 2 . On the upper side of the relay retaining clip 14 there is a recess for snapping in an identification plate 15, so that the relay base 1 can be identified easily and in a clearly visible manner. Finally, the point in the 3 and 4 illustrated relay base 1, 1 'each a further plug-in module 16, in which, depending on the application, for example, a freewheeling diode, a varistor or an RC element can be arranged.

5 finally shows another embodiment of a jumper 8, which is used to bridge the two relay sockets 1, 1' according to FIG 3 and 4 can be used. The plug-in bridge 8 has two plugs 7, 9, each of which has three contact legs, of which at least the middle contact leg is designed to be resilient, so that the plugs 7, 9 can simply be plugged into a bridging connection designed as an opening. In addition, the jumper 8 also has an insulating head 17, which ensures that the plugged-in jumper 8 is safe from being touched.

Claims (6)

Electronics module, in particular a relay base, for mounting on a mounting rail, with a housing (2), at least two conductor connection elements (3, 4), at least one electronic component arranged in the housing (2) or which can be plugged onto the housing (2), in particular a relay ( 5), and a first bridging connection (6), the bridging connection (6) being electrically conductively connected to an associated conductor connection element (3) and being arranged on the same side of the mounting rail (T) as the conductor connection elements (3, 4) and being for the electrical Connection of the bridging connection (6) to a bridging connection (6') of an adjacent electronics module (1'), a plug (7) of a plug-in jumper (8) can be inserted into the bridging connection (6), characterized in that a second bridging connection (10) is provided is, in which a plug (7 ') of a second plug-in bridge (8') can be inserted, the second bridging connection (10) being electrically conductive with the first bridge bridging connection (6) is connected, and that the two bridging connections (6, 10) run in the longitudinal direction (L) of the support rail (T) or in the direction in which the electronic modules (1, 1') are arranged on an end face (11) of the housing (2) are arranged side by side and each a predetermined distance (x ₁ , x ₂ ) from the adjacent have outer edge (12, 13) of the housing (2). electronics module claim 1 , characterized in that the distance (x ₁ , x ₂ ) of the two bridging connections (6, 10) from the respectively adjacent outer edge (12, 13) of the housing (2) is the same. electronics module claim 1 or 2 , characterized in that the electrically conductive connection between the conductor connection element (3) and the first bridging connection (6) and between the two bridging connections (6, 10) is realized by a metal stamped and bent part. electronics module claim 3 , characterized in that the bridging connections (6, 10) are formed as part of the metal stamped and bent part. Electronic module according to one of Claims 1 until 4 , characterized in that the conductor connection elements (3, 4) are designed as screw connection terminals or as tension spring connection terminals. Electronic module according to one of Claims 1 until 5 , with a relay (5) plugged onto the housing (2), characterized in that a relay retaining bracket (14) for mechanically fixing a plugged-in relay (5) can be pivotably fastened to the housing (2).

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