EP0669045A1 - Device for connecting electronic equipment. - Google Patents

Abstract

A multiwire shielded cable (14) for a data network is for example pre-installed in the wall (45) of a building. The end of the cable (14) enters a housing part (66) and is coupled to a Western connector (10) or another connector having a similar design, whatever the connector system that will be later used. When the user-specific equipment is later installed, a modular housing (29) is inserted into the housing part (66). The modular housing (29) has an input tip jack compatible with the connector (10) and another tip jack on the side of the user which may be a jack of the Western type, an IBM data jack or a BNC jack (27). The connector (10) is provided with a metallic shield which directly contacts the shielding of the cable (14) and the metallic shield of the input tip jack, which in turn is electrically connected to the metallic modular housing (29). An easily adaptable data installation system is thus obtained, in which the area from the end of the cable to the user-specific tip jack (27) is very effectively protected against perturbing radiation.

Description

DEVICE FOR CONNECTING ELECTRONIC DEVICES

TECHNICAL AREA

The invention relates to a device for connecting electronic devices to a multi-core, shielded, pre-installed cable, the end of which can be connected to a multi-pin first connector half, comprising a plug adapter which on the one hand has a multi-pin second connector half congruent with the first connector half, and on the other hand has a third connector half, contacts of the second and third connector halves being connected in a predetermined manner by means of a circuit board of the connector adapter.

The cable is pre-installed in the wall of a building, for example, and its end opens into a wall box. Depending on the data network to be installed, system-specific data sockets must be fitted in the wall socket and electrically connected to the cable. So there are such sockets for the IBM system, or for the Western system, or you need BNC sockets. In order to simplify the installation, a first, always uniform plug half is connected to the cable, to which a likewise always uniform second plug half of the plug adapter fits. This means that the first half of the connector can be installed immediately, regardless of which data system is to be used later. It is then only later necessary to insert a plug adapter, the third plug half of which represents the desired socket type. So easy, as it makes the installation of a data system, so easy is the change from one system to another. Only the plug adapter needs to be replaced.

Different types of sockets (third connector halves) are required, for example in the case of a data system for telephone use on the one hand, or a data system for computer use on the other hand, and here again depending on the company-specific system to be used.

STATE OF THE ART

The US company AMP offers a device of the aforementioned type under the name "AMP Communications Outlet Wiring System". The first half of the connector is fixed in an installation housing that is used in a wall socket (or a cable duct outlet). This first connector half is designed as a socket with several (8) spring tongues arranged in a row next to each other, each of which is connected to the wires of the cable via so-called insulation displacement terminals. The insulation displacement clamps are combined to form an insulation displacement terminal block. They enable the electrical connection of the cable wires without having to remove the insulation from the cable wires beforehand. However, they take up a lot of space. The second connector half is formed by several (8) conductor tracks arranged side by side directly on the circuit board. One edge strip is thus designed as a flat plug. The problem with this known device is that the electrical shielding in the transition area between the cable and the second connector half (the conductor tracks of the circuit board) is only brought about by the necessarily quite large-volume metallic installation housing. This must be carried out in a very complex manner in order to meet the high requirements for efficient data networks. Nevertheless, the quality of the shield is limited because of the large distance between the housing walls and the spring tongues / conductor tracks of the first and second connector halves.

PRESENTATION OF THE INVENTION

The object of the invention is to provide a device of the generic type which enables higher-quality electrical shielding. Furthermore, the handling during installation should be simplified, the components should be practical and inexpensive.

This object is achieved in that the first connector half is a connector with a connector housing which, in the direction of insertion, has a plurality of axially parallel channels lying closely next to one another in a plane, into which the fanned out insulated wire ends can each be inserted, transversely in the channel-driven contact lamellae lying in a row next to each other on the one hand pierce the wire insulation and on the other hand form the plug contacts on the outside of the plug housing on the front flat side in the plugging direction, with a substantial part of the rear area of the plug housing in the plugging direction being covered by a metal shield is encapsulated, which partially overlaps the cable end and is electrically connected there directly to the shielding of the cable and that the second connector half is a plug socket corresponding to the plug, the housing of which is likewise to a large extent encapsulated by a metal shield, which at inserted plug with its metal shield is in direct electrical contact.

A plug of this type is known as a so-called Western plug (since it was brought onto the market by Western-Electric). Nevertheless, the invention preferably uses a plug of a basically similar type, namely that its dimensions are modified in such a way that cable cores of larger diameter can be connected. The same applies analogously to the socket.

The advantage of the invention is, on the one hand, that the plug takes up less space, so that more space remains for the cable in the outlet region of the cable, that is to say in the wall socket which is normally to be attached there. This can then be handled more easily. Above all, the electrical shielding takes place in the transition area from the cable to the second half of the plug (the socket) at a short distance from the current-carrying tracks, which means excellent protection against interference.

An advantageous embodiment of the invention is characterized in that the circuit board with the socket and the third connector half is arranged in an at least approximately hollow-prismatic metallic module housing The plug socket is accessible from a rear opening side and the third plug half is accessible from the opposite front opening side and the module housing is in direct electrically conductive contact with the metal shield of the plug socket.

This also shields the transition area to the third half of the connector, but the module housing only appears when the desired module is installed, not when the cable is installed. It is therefore also possible to assign the various plug-in adapters (which differ in the type of the third plug half) to each specifically adapted module housing, as a result of which the shielding quality can be optimized. For example, an IBM data connector (as the third connector half) is considerably larger than a BNC connector. In the case of a uniform shielding housing, which should be matched to the largest socket, large windows would result if only a small socket was used. Interference radiation can then penetrate through such a window or additional shielding masks must be provided. The configuration according to the invention avoids this disadvantage.

Another embodiment of the invention is that the inner surface of the module housing has a plurality of bead-like elevations which bear against the metal shielding of the socket, which deforms it slightly elastically. In this way, contacting which automatically results when installed in the module housing is achieved. The surveys result in several contact points which ensure a higher contact pressure, so that even grease or oxide layers do not impair the perfect contact. term.

If there are further wuist-like elevations on a metal part of the third connector half, their shielding is also securely contacted.

One embodiment of the invention is that the module housing can be clipped onto an approximately disc-shaped support frame, so that the front opening side is arranged near the edge and the rear opening side approximately in the area of the pane center, which support frame has a flat base plane. The support frame is intended and set up to be fastened flat on a wall or a cable duct, so that it surrounds the opening there, from which the cable opens. It then serves as a fastening base for a housing part which includes the installed plug-in adapter including the module housing. The module housing, in which the desired plug adapter is arranged, is held by the supporting frame alone, that is to say, even when the housing part has not yet been installed. This can also be replaced without having to change the electrical installation - for example, if a different design is required.

A further development consists in that the longitudinal axis of the hollow prismatic module housing is inclined by a small angle of inclination with respect to the plane of the pane, so that the lower edge of the rear opening side lies at a smaller distance from the axis of the pane than the lower edge of the front opening side. The advantage of this measure is that, on the one hand, the third connector half of the connector belonging to it can be reached better on the other hand, but above all the cable connected to the first connector half can emerge from the wall with a shorter bend. An angle of inclination between 10 and 20 degrees is recommended.

One embodiment is characterized in that at least one first protrusion protruding rearward approximately parallel to the longitudinal axis is formed on the lower edge of the rear opening side of the module housing and at least one second protrusion protruding downwards transversely to the longitudinal axis is provided on the lower edge of the front opening side. at its free end there is a locking cam that points forwardly parallel to the longitudinal axis. This allows the module housing to be fixed to the support frame in an ergonomically advantageous manner and also detached therefrom.

A further embodiment consists in that the support frame has a support surface for the module housing extending from an edge to approximately the middle, and that at least one bracket-like design is provided on the inner edge of the support surface, under which the first projection can be inserted in a guiding manner and that at least one opening is provided near the outer peripheral edge, into which the second projection can penetrate, the latching cam engaging under the bearing surface of the lower, front, elastically designed edge of the opening.

A further embodiment of the invention consists in that a frame-like housing part can be clipped onto the supporting frame, which housing part has four frame parts which are approximately perpendicular to the base plane of the supporting frame. has walls that are the same height, wherein the support frame is enclosed by the frame walls.

This shape creates space for the cable reaching through the support frame and the module housing to be used. This also results in an aesthetically clear design.

A preferred further development consists in that a cover part is provided, with a cover surface, two side surfaces arranged on opposite side edges, a front surface and a rear surface, an articulated device being formed between the cover part and the frame-like housing part in the region of the rear surface and the side surfaces of the Cover part are approximately triangular in shape, so that the cover surface is oriented obliquely to the base plane when the frame walls of the frame-like housing part and the side surfaces of the cover part abut one another in alignment. This cover design creates additional space in the housing, supports the inclined position of the module housing and accommodates aesthetic requirements.

According to an embodiment of this, it is provided that the rectangular front surface of the cover part has a first cutout that is open at the edge.

This means that when the cover part is closed, a connector can remain inserted in the third connector half. The cable can pass through the cutout from the housing.

In a further development it is provided that the frame wall of the frame-shaped housing part has a second edge-open cutout that complements the first cutout to form an overall cutout.

It is further provided that the support frame can be fastened to it with its base plane lying on a wall and the support frame with a module housing clipped onto it is enclosed by the frame-like housing part and cover part, the third connector half being connected by the first or second cutout or by the Overall section is accessible for a congruent fourth connector half.

A further embodiment preferably consists in that several differently equipped module housings are provided, in which the second connector half is of identical design and the third connector half is different. This causes the system variability mentioned at the beginning.

It is provided that the third connector half is either a BNC socket, or a WESTERN socket or an IBM data socket.

Two WESTERN sockets with a second connector half can also be arranged together on a circuit board.

Similarly, two BNC sockets with a second connector half can be arranged together on a circuit board. Such a tandem version is not possible with IBM data sockets because of their larger space requirement. Advantageously, it is also provided that the support frame is designed to accommodate two module housings which are located next to one another in parallel at a small distance, the support frame being made of electrically insulating material.

This insulation and the distance ensure that there are no unwanted ground loops between the two module housings. Depending on requirements, two identical module housings (with two identical third connector halves) or two different types of module housings can be used.

For this purpose, it is provided that several bow-like configurations and openings are provided, so that a module housing can be attached either in a central position or in one of two symmetrical lateral positions, or that two module housings can each be attached in one of the lateral positions. This means that the equipment and arrangement are flexible.

BRIEF DESCRIPTION OF THE DRAWINGS

It shows:

1 shows a plan view of a first connector half on the flat side with the contact lamellae,

2 shows a corresponding top view of the flat side of a congruent second connector half facing the circuit board,

3 shows a view in the direction of arrow 3 of FIG. 1, 4 shows a view in the direction of arrow 4 of FIG. 2,

5 is a plan view of a support frame with an inserted BNC module housing,

6 shows a sectional view according to the sectional plane 6-6 of FIG. 5,

7 shows a plan view of the support frame according to FIG. 5, with the housing part placed over it with the cover part removed,

8 shows a sectional view according to the sectional plane 8-8 of FIG. 7, the arrangement of the cover part being indicated by dashed lines.

BEST WAY TO CARRY OUT THE INVENTION

The invention is explained in more detail below on the basis of a preferred exemplary embodiment. For better comprehensibility, various details are only shown in simplified or schematic form. This applies in particular to FIGS. 1 to 4, since the plugs and sockets shown here are commercially available or can essentially match them.

According to FIG. 1, a first connector half is designed as a connector TO of the type of a Western connector of a known type. It comprises an approximately prismatic connector housing 11 in which a plurality of axially parallel channels 12 are formed, into which the fanned out insulated wire ends 13 of a cable 14 are inserted. Contact blades 16 are arranged in transverse channels 15, which on the one hand have internal lying cutting ends 17 penetrate the wire insulation and, on the other hand, form the plug contacts 19 (FIG. 3) in the region of the front flat side 18 of the plug housing 11. For better clarity, only five contact blades 16 are shown in FIG. 1, but the standard is eight contact blades.

A substantial part of the rear area of the connector housing 11 in the direction of insertion is covered with a metal shield 21. The end part of the metal shield 21 is bent together to form an enclosure 22 and clamps the shield 20 of the cable 14 which is immersed therebetween and is exposed there.

The second connector half according to FIG. 2 is a socket 23, the housing of which is encapsulated to a substantial extent by a metal shield 24. Not shown are inwardly curved tabs of the metal shield 24, which contact the plug 10 with its metal shield 21 in the inserted state. Therefore, when the plug 10 is inserted into the socket 23, the plug contacts 19 contact contact plates 25 arranged inside the socket 23 and the entire line path from the cable 14 to these contact plates 25 is effectively protected by a metal shield that extends closely around it.

The socket 23 is arranged according to FIG. 4 on a circuit board 26, the outline of which is only indicated by dashed lines in FIG. A third plug half, for example a BNC socket 27 of a commercially available type, is also arranged on the circuit board 26. The required electrical Connection of the contact lamellae 25 to the respective associated contacts of the third connector half is effected by corresponding conductor tracks of the circuit board 26. The circuit board 26 forms a plug adapter 28 with the second plug half (the socket 23) and the third plug half (the BNC socket 27). Different plug adapters differ only with regard to the third plug half.

This plug-in adapter 28 is arranged in an at least approximately hollow-prismatic metallic module housing 29, which has an approximately U-shaped cross section, with a bottom wall 31, two opposite side walls 32 and two opposite end walls 33, 34. The end walls 33, 34 have openings, through which the socket 23 on the one hand and the BNC socket 27 on the other hand are accessible. The edges of the openings close around the socket 23 and the part of the BNC socket 27 passing through in such a way that the radiation of interference fields is avoided. The upper end of the module housing 29 forms a metallic cover plate 35 which is guided, for example, in guide grooves 36 in the side walls 32. A plurality of bead-like elevations 37 are formed on the cover plate 35 in such a way that they press elastically with pretension against the metal shield 24 of the socket 23 and against the metal body of the BNC socket 27. Similar elevations can also be formed on the side walls 32. This ensures that the module housing 29 is inevitably electrically connected to the sockets of the plug adapter 28.

To keep the presentation clear, is only in Fig.2 the outline of the module housing 29 indicated by dashed lines. 4 shows a relatively large free space in the module housing 29 below the circuit board 26. This is because the BNC socket 27 shown here as an example has a low overall height. The inside dimension of the module housing 29, however, is matched to the largest IBM data socket to be used. Although the opening in the end wall 34 must be considerably wider for this, this adaptation can be achieved by wall segments which can be broken out at predetermined breaking edges, since the module housing 29 is produced in a somewhat complex manner as a die-cast metal, it is significantly less expensive if only one Kind of module housing 29 is manufactured.

On the lower left edge (according to FIG. 4), a first projection 38 is formed, which protrudes rearward parallel to a longitudinal axis of the module housing 29 and protrudes from the end wall 33 in the manner of a nose. A further projection of the same design is not visible in FIG. 4, since it is covered by the projection 38 in the view. The end wall 34 merges into the bottom wall 31 via a low step 39. The purpose is that a lever tool (a knife tip) can be used here to release the module housing 29 from the anchorage, which will be explained later. Following this step, a second projection 41 projecting downward transversely to the longitudinal axis is formed on the bottom wall 31. The second projection 41 carries at its free end at a distance from the bottom wall 31 an approximately parallel to the longitudinal axis forward (in the direction of the end wall 34) locking cams 42. There is another, identical in shape to this second projection 41, in Fig. 4 invisible projection. 5 and 6 show an approximately disk-shaped support frame 43 with a flat base plane 44, with which the support frame is placed on a wall 45 of a cable duct or a building, so that it covers the wall opening 46. The wall 45 is indicated by dashed lines in FIG. 6 only for orientation. The outline of the support frame 43 in the plan view of Figure 5 is square with rounded corners. In the middle area it has an opening 46 which occupies a considerable area. Around the opening, a wall base 48 stands vertically high from the base plane 44, which is approximately U-shaped in plan view. It serves as a stiffening of the support frame and also contains locking recesses 52 and 53 on opposite outer sides 49 and 51, the purpose of which will be explained later.

A support surface 54 extends between the ends of the U-legs of the wall base 48 and extends approximately from the right edge to approximately the center of the support frame

43 is enough. In the transverse direction it takes up almost the entire width of the support frame. In the example shown in FIG. 6, the top of the bearing surface 54 is at an angle of inclination of approximately 12 degrees with respect to the base plane

44 aligned. It is understood that angles of inclination between 10 and 20 degrees can be carried out. On the inner edge of the support surface 54, a bar 56 which is perpendicular to this is formed. It has four recesses 57, 58, 59, 61, which are distributed at equal intervals, into which the first projections 38 of a module housing 29 can engage. The sectional view according to FIG. 6 does not correctly follow the course of the sectional plane in FIG. 5 because the opening 57 would then not have been cut open. As a result of the aforementioned openings, the web 56 receives one bow-like training. Near the edge 55, four openings 62, 63, 64, 65 are also formed in the bearing surface 54 distributed at equal intervals. The aforementioned second projections 41 can dip into them and engage with their locking cams under the bearing surface. Since the support frame 43 is made of plastic, the edge zone in front of the metallic locking cams 42 can yield elastically when a module housing is engaged or disengaged. FIGS. 5 and 6 show a module housing 29 in one of the three possible latching positions. Because of the same distance between the recesses 57-61 and openings 62-65, the module housing can be used in the center, as in the other edge position. Two module housings can also be arranged in the two edge positions. A module housing is disengaged with the support of, for example, a knife tip, which can be used as a lever between the step 39 and the support surface 54.

7 and 8, a frame-like housing part 66 is shown, which is put over the support frame 43. The housing part 66 has four frame walls 67, 68, 69, 71, each rising vertically from the base plane 44 and having the same height (for example 2.5 cm). Web projections 72 and 73 protrude from the opposite inner sides of the frame walls 67 and 69, the inner cantons 74, 75 of which engage in the recesses 52, 53 shown in FIG. 5, whereby the housing part 66 is fixed in its position on the support frame 43 .

A cover part 76 which completes and closes the housing part 66 is indicated by a dashed line in FIG. He has one Cover surface 77, two opposite, approximately triangular side surfaces 78, a front surface 79 and a rudimentary rear surface 81 in the form of a cylinder jacket section, which runs coaxially to a pivot axis about which the cover part 76 is pivotally mounted relative to the housing part. For this purpose, two brackets 82, 83 protrude from the housing part, which have pins 84, 85 directed towards one another. These engage in corresponding holes in struts (not particularly shown) in the corner region of the top surface 76 and rear surface 81. On the inside of the frame wall 71, a spring clip 86 is also formed, which presses against a cam in the corner region of the rear surface 81, which is also not particularly shown, and causes the cover part to be prestressed into the closed position.

8 illustrates that the inclined position of the module housing 29 means that the cable 14 is given a moderately curved course. This reduces mechanical stresses exerted by the cable on the connector 10. In the rectangular front surface 79 of the cover part 76, a first cutout 87 open to the edge is indicated, through which the BNC socket 27 is accessible even when the cover part is closed. In connection with an IBM data socket, it is necessary to also make a second cutout open in the frame wall 68. This can advantageously be achieved by a wall piece that can be broken out along predetermined breaking lines. The two sections then complement each other to form an overall rectangular or oblong oval section.

Claims

PATENT CLAIMS

1.Device for connecting electronic devices to a multi-core shielded, pre-installed cable, the end of which can be connected to a multi-pin first connector half, comprising a plug adapter which on the one hand has a congruent multi-pin second connector half and on the other hand has a third connector half, contacts of which second and third plug half are electrically connected in a predetermined manner by means of a circuit board of the plug adapter, characterized in that the first plug half is a plug (10) with a plug housing (11) which extends a plurality closely in one plane in the plug-in direction has adjacent, axially parallel channels (12) into which the fanned out insulated wire ends (13) can each be inserted, contact strips (16) which can be driven transversely into the channels (12) in a row lying next to one another pierce the wire insulation and others on the other hand, on the outside of the plug housing (11) form the plug contacts (1 g) on the front flat side (18) in the plugging direction, a substantial part of the rear area of the plug housing (11) in the plugging direction being encapsulated by a metal shield (21), which partially overlaps the cable end and there is directly connected to the shield (20) of the cable (14) and that the second connector half is a socket (23) corresponding to the connector (10), the housing of which is also to a large extent made of a metal shield ¬ mung (24) is encapsulated, which is in direct electrical contact when the plug (10) is inserted with its metal shield (21).

2. Device according to claim 1, characterized in that the circuit board (26) with the socket (23) and the third connector half (27) is arranged in an at least approximately hollow prismatic module housing (29), one from the rear The socket (23) on the opening side and the third connector half (27) are accessible from the opposite front opening side and the module housing (29) is in direct electrical contact with the metal shield (24) of the socket (23).

3. Apparatus according to claim 2, characterized in that the inner surface of the module housing (29) has a plurality of bead-like elevations (37) which rest on the metal shield (24) of the socket (23), which is slightly elastically deforming.

4. The device according to claim 3, characterized in that further bead-like elevations (37) rest on a metal part of the third connector half (27).

5. The device according to claim 2, characterized in that the module housing (29) can be clipped onto an approximately disk-shaped support frame (43), so that the front opening side is arranged near the edge (55) and the rear opening side approximately in the area of the disc center, which support frame (43) has a flat base plane (44).

6. The device according to claim 5, characterized gekenn¬ characterized in that the longitudinal axis of the hollow prismatic module housing (29) relative to the disc plane by one Small angle of inclination is oriented inclined so that the lower edge of the rear opening side is less close to the plane of the pane than the lower edge of the front opening side.

7. The device according to claim 6, characterized g e k e n n ¬ z e i c h n e t that the angle of inclination is between 10 and 20 degrees.

8. The device according to claim 6, characterized in that at the lower edge of the rear opening side of the module housing (29) is formed at least one approximately parallel to the longitudinal axis backwards projecting first projection (38) and at least one transverse at the lower edge of the front opening side A second projection projecting downward from the longitudinal axis is provided, at the free end of which a locking cam (42) is provided which points forwardly parallel to the longitudinal axis.

9. The device according to claim 8, characterized in that the support frame (43) has a support surface (54) for the module housing (29) extending from an edge (55) to approximately the middle, that on the inner edge of the support surface (54 ) at least one bow-like design (56) is provided, under which the first projection (38) can be pushed in and that near the outer edge (55) there is at least one opening (62, 63, 64, 65) into which the second projection (41) can be immersed, the latching cam (42) engaging under the bearing surface (54) engaging over the lower front, elastically evasive edge of the opening.

10. The device according to claim 5, characterized in that a frame-like housing part (66) on the support frame (43) can be clipped, which housing part (66) four each from the base plane (44) of the support frame (43) approximately vertically projecting frame walls (67, 68, 69, 71) which are of equal height, the supporting frame (43) being enclosed by the frame walls.

11. The device according to claim 10, characterized in that a cover part (76) is provided with a cover surface (77), two on opposite Seiten¬ edges arranged side surfaces (78), a front surface (79) and a rear surface (81 ), a joint device (84, 85) being formed between the cover part (76) and the frame-like housing part (66) in the region of the rear surface (81) and the side surfaces of the cover part (76) being approximately triangular, so that the cover surface (77 ) is aligned obliquely to the base plane (44) when the frame walls (67, 68, 69, 71) of the frame-like housing part (66) and the side surfaces (78, 79) of the cover part (76) meet in alignment with one another.

12. The apparatus according to claim 11, characterized in that the rectangular front surface (79) of the cover part (76) has a first cutout (87) which is open at the edge.

13. The apparatus according to claim 12, characterized in that the frame wall (68) of the frame-shaped housing part (66) adjoining the front surface (79) of the lid part (76) has a second cutout which is open to the edge and which corresponds to the first cutout (87) added to a total.

14. The apparatus of claim 12 or 13, characterized g e- indicates that the support frame (43) with its base plane (44) on a wall (45) lying thereon can be fastened and the support frame (43) with a module housing clipped onto it ( 29) is enclosed by the frame-like housing part (66) and cover part (76), the third connector half (27) being accessible through the first or second cutout (87) or through the overall cutout for a congruent fourth connector half.

15. The apparatus according to claim 2, characterized in that several differently equipped module housings are provided, in each of which the second connector half (23) is of identical design and the third connector half is different.

16. The apparatus according to claim 15, characterized g e k e n n- z e i c h n e t that the third connector half is a BNC socket (27).

17. The apparatus of claim 15, characterized g e k e n n - z e i c h n e t that the third connector half an WESTERN-

Socket.

18. The apparatus according to claim 15, characterized in that the third connector half is an IBM data connector.

19. The apparatus according to claim 17, characterized in that in the module housing two WESTERN sockets are arranged on the one hand with a common second connector half.

20. The apparatus of claim 5, characterized g e k e n n ¬ z e i c h n e t that the support frame (43) is arranged to accommodate two module housings (29) lying parallel next to one another at a small distance, the support frame (43) being made of electrically insulating material.

21. The apparatus of claim 9 and 20, characterized g- indicates that a plurality of bracket-like configurations and openings are provided so that a module housing (29) can be attached either in a central position or in one of two symmetrical lateral positions, or that two module housings can each be attached in one of the lateral positions.