The invention relates to a semiconductor relay having an essentially cuboid housing. A semiconductor relay is known, for example, from DE 199 56 445 C2.
A semiconductor relay or semiconductor contactor has connections for a main circuit or load circuit and for a control circuit. If additional functions, for example a monitoring or measurement function, are intended to be provided, then these are normally implemented with the aid of an additional appliance which is connected to the appropriate circuit or to the appropriate circuits. In this case, different appliances may be provided in particular for different monitoring functions, with the load circuit requirements being independent of the use of these appliances. The plurality of the appliances which can optionally be used involves considerable additional effort for configuration, storage, installation and commissioning in comparison to the use of exclusively one semiconductor relay or semiconductor contactor. Furthermore, the space requirement for the appliances to be installed in addition to the relay or contactor in a switchgear cabinet is significant.
The invention is based on the object of providing additional functions in circuits having a semiconductor relay or semiconductor contactor with particularly little installation effort, and with a particularly small amount of space being required.
According to the invention, this object is achieved by a semiconductor relay having the features of claim 1. The expression semiconductor relay in this case also covers appliances which are normally referred to as semiconductor contactors. The semiconductor relay has an essentially cuboid housing which can be attached to a holding apparatus, in particular a mounting rail, or to a heat sink, for example, by a face which is referred to as an attachment face. The other five faces of the housing are referred to jointly as connecting faces. Electrical connections are provided on one or more of these faces. A functional module which can be fitted to the housing can be connected to at least one of the connecting faces. A single functional module preferably makes contact with the housing on a plurality of faces, in particular on a side surface which is arranged at right angles to the attachment face and on a front face which is opposite the attachment face. In this case, by way of example, it is possible to provide for one face of the housing to be only mechanically connected to one face of the functional module, while a further face of the housing is connected both mechanically and electrically to a further face of the functional module. The functional module is connected to the control circuit and/or to the load circuit of the semiconductor relay.
The connection of the functional module to the housing of the semiconductor relay can preferably be produced and detached without the use of any tools, in particular by means of a snap-action connection. Alternatively or additionally, however, it is also possible to provide a screw connection, by way of example. A plurality of functional modules can preferably be coupled to a single housing of a semiconductor relay. The connection can likewise be provided between a plurality of functional modules.
The functional module which can be fitted to the relay housing is preferably no broader—with respect to the extent of a mounting rail—than the housing itself, so that the arrangement comprising the semiconductor relay and functional module requires virtually no additional space in a switchgear cabinet. The functional module is also distinguished by the capability to be retrofitted in existing switchgear installations in a very simple manner.
The mechanical and the electrical connection of the functional module to the semiconductor relay may be made successively or at the same time. The production of the electrical connection between the functional module and the semiconductor relay to the connection of the respective housing minimizes the wiring complexity, and at the same time provides protection against wiring errors. In this case corresponding contact-making elements, for example spring contacts, are provided in the housing of the semiconductor relay and in the functional module, and allow contact to be made with the drive electronics for the semiconductor relay, so that the functional module can directly influence the drive in the semiconductor relay. The electrical characteristics of the semiconductor relay to which the functional module has been added are preferably identical to the characteristics of a branch without any additional functions. This independence of the electrical characteristics of the main circuit or load circuit from the presence and the characteristics of the functional module means rational configuration as well as considerable savings for storage. Overall, the semiconductor relay and the functional modules which are compatible with it provide a product range which can be extended in a universal modular form, with the semiconductor relay also being operable without any restrictions with no functional module connected to it.
In order to make particularly good use of the space which is available for installation of the functional module in a switchgear cabinet and which is adjacent to the semiconductor relay, one preferred refinement of the functional module has not only a part which is adjacent to the front face of the semiconductor relay but also a part which is adjacent to one side surface, specifically a side surface which is aligned parallel to the mounting rail. The last-mentioned part in this case has a so-called base face, which is at least approximately aligned with the attachment face of the semiconductor relay. This base face is preferably opposite a plug connector strip on the front face of the functional module.
If the housing of the semiconductor relay has an opening which is also intended to remain accessible when the functional module is fitted, then, according to one preferred embodiment, two attachment limbs are integrally formed on the functional module on both sides of the opening, and are preferably provided in order to produce a snap-action connection between the functional module and the housing of the semiconductor relay. The attachment limbs are in this case aligned parallel to two side surfaces of the housing, provided that the opening is located on the front face of the housing, with the snap-action connection elements of the attachment limbs having the capability to be latched to the housing of the semiconductor relay, on an edge between the front face and one side surface of the housing.
The functional module may, for example, cover one or more functions: monitoring of the load circuit, power control in the load circuit, current measurement, analogue/digital signal conversion. The functional module may be drivable by means of analogue and/or digital signals. The advantage of the invention is, in particular, that prefabricated functional modules, and/or functional modules which can be retrofitted and can be snapped onto a semiconductor relay or a semiconductor contactor allow the functionality of the relay to be extended in a modular, simple form, and/or allow additional functions to be provided, preferably in the control circuit.
A plurality of exemplary embodiments of the invention will be explained in more detail in the following text with reference to a drawing, in which:
FIGS. 1 to 3 each show one exemplary embodiment of a functional module for a semiconductor relay,
FIGS. 5 to 8 each show one exemplary embodiment of a semiconductor relay,
Mutually corresponding parts are provided with the same reference symbols in all of the Figures.
FIGS. 1 to 3 each show one embodiment of a functional module 1 for a semiconductor relay or a semiconductor contactor. The functional module 1 acts at least on the control circuit of the semiconductor relay and replaces conventional appliances which have to be physically connected to the semiconductor relay in order to drive it.
The functional modules 1 illustrated in FIGS. 2 to 4 are essentially L-shaped, with the first, longer L limb resting on the front face 8 of the semiconductor relay 2, and the second, shorter L-limb resting on the lateral face 7. The last-mentioned L-limb is bounded by a base face 16, which is arranged as a straight-line extension of the attachment face 3 of the semiconductor relay 2. A fixing face 17 of the functional module 1 runs at right angles to the base face 16, adjacent to the lateral face 7, and has a groove 18 which interacts with a rail 19 (which is used as a corresponding mechanical connection element) on the lateral face 7 of the housing 20 of the semiconductor relay 2. The functional module 1, whose housing 32 is produced from plastic in the same way as the housing 20 of the semiconductor relay 2, can thus be pushed onto it. A snap-action connection 21 is provided on the opposite lateral face 6 and fixes the functional module 1 on an edge 22 of the housing 20. The snap-action connection 21 is formed from two snap-action hooks 23, which latch in depressions 24, which form further mechanical connection elements, on the lateral face 6. The snap-action hooks 23 are integrally formed in a sprung manner on in each case one attachment limb 25 on the functional module 1, which is aligned parallel to the longitudinal faces 4, 5. A free space remains between the attachment limbs 25 in order to ensure accessibility to an opening 26, which is associated with the main connection 9, in the housing 20 even after the functional module 1 has been snapped onto it. A further opening 27, which is associated with the main connection 10, in the housing 20 is accessible through an operating opening 28 in the housing 32 of the functional module 1. A plug connecting strip 29 is located on the front face of the functional module 1, opposite the base face 16.
FIGS. 5 to 8 each show a semiconductor relay 2, with the embodiment illustrated in
In the exemplary embodiment shown in
The exemplary embodiment illustrated in
Number | Date | Country | Kind |
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03007172.4 | Mar 2003 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/01175 | 2/9/2004 | WO | 9/27/2005 |