DE102012015037A1 - electronic module - Google Patents

Abstract

An electronic module, in particular a relay socket, is shown and described for mounting on a mounting rail, with a housing (2), at least two conductor connection elements (3, 4), at least one arranged in the housing (2) or that can be plugged onto the housing (2) Electronic component, in particular a relay (5), and a first bridge connection (6), the bridge connection (6) being connected in an electrically conductive manner to an associated conductor connection element (3) and with a bridge connection (6 ') for the electrical connection of the bridge connection (6) ) of an adjacent electronic module (1 '), a plug (7) of a plug-in bridge (8) can be inserted into the bridge connection (6). In the electronic module according to the invention, electronic modules with different overall widths can be easily bridged by providing a second bridge connection (10) into which a plug (7 ') of a second plug-in bridge (8') can be inserted, the second bridge connection ( 10) is electrically conductively connected to the first bridge connection (6), and that the two bridge connections (6, 10) are arranged next to one another on an end face (11) of the housing (2) running in the longitudinal direction of the mounting rail and each 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 socket, for placement on a mounting rail, with a housing, at least two conductor connection elements, at least one arranged in the housing or attachable to the housing electronic component, in particular a relay, and a first bridge connection, wherein the bridging terminal electrical is conductively connected to an associated conductor connection element and wherein for the electrical connection of this bridge connection with a bridging terminal of an adjacent electronic module, a plug of a jumper in the bridge connection can be inserted.

Electronic modules and electronic devices for mounting 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 clipped onto mounting rails, the electronic modules in question have at least two conductor connection elements, with predominantly screw terminals or tension spring terminals being used as conductor connection elements. In addition, for some years also leg spring terminals are increasingly used, which are also referred to as direct terminals, as they allow the direct connection of a rigid or provided with a wire end conductor, without the clamping point - as in tension spring terminals - must be opened before.

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

Relay sockets are typically connected by single lines, which leads to a relatively high wiring complexity, if - as in practice in mechanical and plant engineering rule - a plurality of relays must be electrically connected via the individual relay socket. In order to reduce the wiring complexity, the connection elements of the same potential are electrically connected to one another, in particular in the case of relay sockets or electronic modules mounted adjacent to a mounting rail. This electrical connection of individual conductor connection elements could be realized in the simplest case by means of individually tailored individual lines, which would not significantly reduce the wiring complexity.

Therefore, in practice, jumpers are often used, which have at least two connectors, which can each be plugged into a bridging terminal of two adjacent electronic modules. Such jumpers can also have more than two plugs, so that they can be electrically conductively connected to each other a corresponding plurality of electronic modules. Such jumpers, which are often referred to as a cross connector, are for example from the DE 195 42 628 C1 known, wherein the cross-connector disclosed in this document has the peculiarity that it consists of at least two double-layered transverse connector pieces, which are connectable to each other, so that the cross connector can be easily extended.

The disadvantage of jumpers is that they have a predetermined by the distance of the plug fixed grid width, so that jumpers can only be used if the electronic modules have a corresponding grid width. For example, since relay sockets often have a width of 30 mm, provided for use in such relay sockets cross connector, regardless of whether they have two or more plugs, also have a pitch of 30 mm. As a result, different jumpers with correspondingly different grid widths are required for bridging relay sockets with different widths.

An alternative bridging concept is the use of distribution-independent or divisional cross connectors, as for example from the DE 296 11 543 U1 are known. Through the use of such divisional cross connector and the corresponding design of the relay socket with a corresponding cross connector shaft while it is possible to bridge relay socket with each other, which have a different width, the maximum number of such bridgeable relay socket is dependent on the width of the base and the length of the cross connector. Thus, on the one hand limits the maximum number of relay socket to be bridged, on the other hand, if necessary, the length of the cross connector must be individually shortened 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, after the aforementioned disadvantages Possibility to avoid and specify a bridging concept or an electronic module with which a simple bridging of electronic modules with different widths is possible.

This object is achieved in the electronics module described above with the features of claim 1, characterized in that a second bridging connection is provided, in which a plug of a second jumper is inserted, wherein the second bridging terminal is electrically connected to the first bridging terminal. The two bridging connections are arranged next to one another on a front side of the housing extending in the longitudinal direction of the mounting rail or in the arrangement direction of the electronic modules, wherein the two bridging connections each have a predetermined distance from the adjacent outer edge of the housing. The inventive arrangement of a second bridge connection, which is electrically connected to the first bridge connection, and the positioning of the two bridging connections with a predetermined distance from the respective adjacent outer edge of the housing, the bridging of two adjacent electronic modules can be realized in that the two connectors a jumper in the two adjacent bridging terminals of the two adjacent electronic modules are plugged.

In the case of several relay sockets arranged next to one another, the arrangement of the potentials-plus-pole and minus-pole-is always alternating in the relay sockets, with a bridging connection always being electrically conductively connected to only one potential. The result of this is that the grid width of the jumper must correspond to the width of the relay socket since the jumper always has to jump over a bridging connection with its two plugs. Since in the electronic module according to the invention, the two Steckereiner jumper are inserted into the two adjacent bridging terminals of two adjacent electronic modules, the distance between two bridging terminals or two poles in the housing of a bridging module has no effect on the required grid width of the jumper, so that even for electronic modules with different Construction widths can always be the same type jumper with the same grid width can be used.

For the user, this has the advantage that relay sockets of different widths can be bridged with each other, for which, however, only one jumper type is required. In addition, the number of electronic modules that can be bridged with each other is not limited; It can always be bridged yet another electronic module with another jumper. Finally, it is also not necessary to shorten the jumper depending on the number or width of the electronic modules or otherwise assemble.

According to an advantageous embodiment of the electronic module according to the invention, the distance between the two bridging connections from the respective adjacent outer edge of the housing is the same size, d. H. Both bridging connections are equidistant from the respective adjacent outer edge. The required locking width of a jumper then corresponds to twice the distance of a bridging connection from the adjacent outer edge of the housing and is thus - as previously stated - regardless of the width of the housing.

The electrically conductive connection between the one conductor connection element and the first bridging connection and between the two bridging connections can preferably be realized by a metallic stamped and bent part. As a result, the electrical connection can be made particularly simple. Preferably, the bridging connections are formed as part of the metallic 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, then the bridging connections can be realized simply as openings punched out of the stamped and bent part into which the plugs of the jumper are inserted.

If the preferred embodiment of the electronic module is a relay socket with a relay plugged onto the housing as an electronic component, preferably a relay retaining clip for the mechanical fixation of the plugged-on relay is fastened to the housing in a pivotable manner. At the Relaishaltebügel can preferably also be a web or a projection formed such that an inserted relay can be ejected from the relay socket by pivoting the Relaishaltebügels. The Relaishaltebügel then in addition to its holding and security function also has an ejection function. In addition, the Relaishaltebügel preferably has a marking surface on which a corresponding label can be attached or locked, so that the relay socket can be easily and clearly marked.

In particular, there are a variety of ways to design and further develop the electronic module according to the invention. Reference is made to both the claims subordinate to claim 1 and to the following description with reference to the figures. In the drawing show

1 a schematic representation of a bridging concept in electronic modules according to the prior art,

2 a schematic representation of the Brückungskonzepts in electronic modules according to the invention,

3 a perspective view of two adjacent, inventive electronic modules,

4 the two electronic modules according to 3 in the side view, and

5 An embodiment of a jumper for use in electronic modules according to the invention.

Based on 1 and 2 , each schematically three juxtaposed electronic modules 1 . 1' . 1'' show the difference between the bridging concept according to the prior art ( 1 ) and the bridging concept according to the invention ( 2 ). The electronic modules 1 . 1' . 1'' that in the 1 and 2 are shown only schematically, each have a housing 2 on, in which two conductor connection elements 3 . 4 are arranged. Not shown in the 1 and 2 that on or in the case 2 the electronic modules 1 . 1' . 1'' in each case still an electronic component can be plugged or inserted.

In the 1 illustrated electronic modules 1 . 1' and 1'' each have two bridging connections 6 . 10 on, with the first bridge connection 6 with the first conductor connection element 3 and the second bridge connection 10 with the second conductor connection element 4 is electrically connected. For connecting two equal potentials of two electronic modules 1 . 1' must in the known from the prior art electronic modules 1 . 1' . 1'' the first plug 7 a jumper 8th in the first bridge connection 6 of the first electronic module 1 and the second plug 9 the jumper 8th in the first bridge connection 6 ' of the second electronic module 1' be plugged in.

How out 1 can be seen, the second bridge connection must 10 of the first electronic module 1 from the jumper 8th be skipped, so from the jumper 8th or the two plugs 7 . 9 the bridging connections 6 . 6 ' be contacted, who lead the same potential. This inevitably leads to the grid width of the jumper 8th ie the distance between the two plugs 7 . 9 , the width of the electronics module 1 must correspond. Assign the electronic modules 1 . 1' . 1'' different widths, as in the schematic representation according to the 1 and 2 This is the case with the electronics modules known from the prior art 1 . 1' . 1'' to that for bridging the electronic modules 1 . 1' . 1'' two jumpers 8th . 8th' are needed, both of which have a different grid width. Because the second electronic modules 1' a small width as the first electronic modules 1 has, the second jumper must 8th' a correspondingly smaller grid width than the first jumper 8th to have.

While in the known electronic modules 1 . 1' . 1'' corresponding 1 the two bridging connections 6 . 10 each with a conductor connection element 3 . 4 are electrically connected, is in the electronic modules according to the invention 1 . 1' . 1'' corresponding 2 in each case the second bridging connection 10 electrically conductive with the first bridging connection 6 connected. The two bridging connections 6 . 10 , the side by side on the extending in the longitudinal direction of the support rail end face 11 of the housing 2 are arranged, always have a predetermined distance x ₁ or x ₂ from the respective adjacent outer edge 12 respectively. 13 of the housing 2 on while the distance between the jumper connections 6 . 10 to each other depending on the width of the electronic modules 1 . 1' . 1'' is different.

The bridging of adjacent electronic modules 1 . 1' . 1'' can then be done by a plug 7 a jumper 8th in the second bridging connection 10 of the first electronic module 1 and the second plug 9 the jumper 8th in the adjacent first bridge connection 6 ' of the adjacent second electronic module 1' is inserted. The grid width of the jumper 8th no longer depends on the width of the electronic modules 1 . 1' . 1'' but only from the distance x _{1 of} the first bridge connection 6 from the adjacent outer edge 12 of the housing 2 and the distance x _{2 of} the second bridge connection 10 from the neighboring edge 13 of the housing 2 from. If the distance x _{1 of} the first bridge connection 6 from the first edge 12 the distance x _{2 of} the second bridge connection 10 from the second, opposite edge 13 corresponds to the housing, so must the grid width of the jumper 8th equal to twice the distance x ₁ , x ₂ , assuming the two electronic modules to be bridged 1 . 1' are arranged directly adjacent to each other. Based on the representation according to 2 It can be seen that in the bridging concept according to the invention for bridging three electronic modules 1 . 1' . 1'' with different widths two jumpers 8th . 8th' can be used, which have the same grid width. The user thus also requires electronics modules 1 with different widths always only one jumper type with a 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. On the case 2 the two relay sockets 1 . 1' is in each case a relay 5 . 5 ' attached via the conductor connection elements 3 . 4 in the relay sockets 1 . 1' are arranged, can be connected electrically. The in the 3 and 4 illustrated relay socket 1 . 1' furthermore, each still have a Relaishaltebügel 14 for the mechanical fixation of an attached relay 5 on, with the Relaishaltebügel 14 swiveling on the housing 2 are stored. On top of the Relaishaltebügel 14 is a recess for locking a label 15 designed so that the relay socket 1 can be easily and clearly marked. Finally, in the 3 and 4 illustrated relay socket 1 . 1' each still another plug-in module 16 on, in which, depending on the application, for example, a freewheeling diode, a varistor or an RC element can be arranged.

5 Finally, shows an embodiment of a jumper 8th leading to the bridge of the two relay sockets 1 . 1' according to the 3 and 4 can be used. The jumper 8th has two plugs 7 . 9 on, each having three contact legs, of which at least the middle contact leg is resilient, so that the plug 7 . 9 can be easily plugged into a trained as an opening bridge connection. In addition, the jumper points 8th another insulating head 17 on, a touch safety of the inserted jumper 8th guaranteed.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19542628 C1 [0005]
• DE 29611543 U1 [0007]

Claims (6)

Electronic module, in particular relay socket, for mounting on a mounting rail, with a housing ( 2 ), at least two conductor connection elements ( 3 . 4 ), at least one in the housing ( 2 ) or on the housing ( 2 ) attachable electronic component, in particular a relay ( 5 ), and a first bridge connection ( 6 ), whereby the bridging connection ( 6 ) electrically conductive with an associated conductor connection element ( 3 ) and wherein for the electrical connection of the bridging connection ( 6 ) with a bridging connection ( 6 ' ) of an adjacent electronic module ( 1' ) a plug ( 7 ) of a jumper ( 8th ) into the bridge connection ( 6 ) is inserted, characterized in that a second bridge connection ( 10 ), in which a plug ( 7 ' ) a second jumper ( 8th' ) is insertable, wherein the second bridge connection ( 10 ) electrically conductive with the first bridging connection ( 6 ), and that the two bridging connections ( 6 . 10 ) on a longitudinal side of the support rail extending end face ( 11 ) of the housing ( 2 ) are arranged side by side and each have a predetermined distance (x ₁ , x ₂ ) from the adjacent outer edge ( 12 . 13 ) of the housing ( 2 ) exhibit. Electronics module according to claim 1, characterized in that the distance (x ₁ , x ₂ ) of the two bridging connections ( 6 . 10 ) from the respective adjacent outer edge ( 12 . 13 ) of the housing ( 2 ) is the same size. Electronics module according to claim 1 or 2, characterized in that the electrically conductive connection between the conductor connecting element ( 4 ) and the first bridge connection ( 6 ) and between the two bridging connections ( 6 . 10 ) is realized by a metallic stamped and bent part. Electronics module according to claim 3, characterized in that the bridging connections ( 6 . 10 ) are formed as part of the metallic stamped and bent part. Electronics module according to one of claims 1 to 4, characterized in that the conductor connection elements ( 3 . 4 ) are designed as screw terminals or Zugfederanschlussklemmen. Electronics module according to one of claims 1 to 5, with a housing ( 2 ) plugged relays ( 5 ), characterized in that a relay holding bracket ( 14 ) for mechanically fixing an inserted relay ( 5 ) pivotable on the housing ( 2 ) is attachable.

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