NO334385B1 - Switch device. - Google Patents

Abstract

The invention relates to a circuit breaker (1), in particular, a residual current circuit breaker, comprising functional groups arranged in a housing (3), such as a detection unit, trip relay, breaker mechanism (45), breaker contacts (43), a monitoring device (4), and input and output contact terminals. According to the invention, rapid matching to the application requirements may be achieved, whereby at least one housing (7), for at least one electronic control and/or regulation module (8) is provided, which, on preferably cable-free installation in the housing (7), is connected to contacts (9), which are connected to at least one functional group and, optionally, with the input and output side connector terminals.

Description

The invention relates to a switch device, in particular a fault current protection switch, which comprises functional groups arranged in a housing, such as detection unit, release relay, switch lock, switch contacts and also connection terminals on the input and output side, whereby at least one holder for at least one electronic control and/or regulation module , which is inserted in the holder, preferably cableless, is connected to contacts which are connected to at least one function group and occasionally to the connection terminals on the input side and/or output side, and where a, preferably frame-like, base for the electronic control and /or the regulation module, where the base has first contacts for wireless connection with the electronic control and/or regulation module, and other contacts for, preferably wireless, connection with the contacts associated with at least one functional group and occasionally with the connection terminals on the input side and/or output side .

Such switch devices take over many connection and, above all, safety tasks within installation technology.

Residual current protection switches serve to separate sections of an electrical supply system from a voltage source in the event of a residual current, for example caused through an insulation fault. Such residual current protection switches are, with regard to their mode of operation, divided into mains voltage-independent and mains voltage-dependent residual current protection switches, where the voltage dependence relates to the function of the detection of residual current and also the release unit.

When there is an insulation fault, the fault current resulting from it is registered by the detection unit and a trip signal is sent out to the trip relay which, in further sequence, over a switch lock to divide the contacts and which thus leads to a disconnection of the faulty distribution system from the voltage source.

According to the state of the art, residual current protection switches with standardized values with respect to residual current amplitudes (e.g. 10 mA, 30 mA, 100 mA), residual current quality (e.g. pure sine current = "AC", pulsating sine current with direct current component = "A" , direct current = "B", and also classified according to the nature of tripping (non-delayed, short-time delayed, selective). Constructively, these variants are only solved with certain fixed parameters, whereby the purpose of application of the residual current protection switch emerges.

The disadvantages of these residual current circuit breakers are that each is only suitable for a specific requirement. Through the many possible designs, there is a large effort in parts, which leads to high costs. In addition, above all residual current protection switches with a deviating application profile from the usual design, when perhaps detection of unusual residual currents is required, are particularly effort-intensive to manufacture. Furthermore, already installed residual current circuit breakers cannot be used for properly changed tasks but can only be replaced, which not only leads to the replacement of an intrinsically intact component, but also to significant costs.

In many countries, only mains voltage-independent circuit breakers are permitted.

The disadvantages of mains voltage-independent protection switches are that, in principle, these only have certain basic functions which, through the mandated mains voltage independence, cannot be extended, perhaps to improve the fault solution.

From US 5 162 766 a circuit breaker with a recess for holding an electronic trip unit is known. Depending on the design, other modules can also be added. Certain functions are assigned to a separate board.

US 5 841 616 describes a protection switch, on which a module with various additional functions, especially indication and control functions can be built. In this additional module, which is optionally there or can also be omitted, is that there is also a test device with a test key.

US 6 175 289 Bl Describes a protection switch comprising a housing with a holder for an electronic control and regulation module.

US 5 877 691 describes a protection switch which is made up of several modules. These are connected to each other via mechanical connection elements and microswitches.

The task of the invention is therefore to further design a switch device, in particular a residual current protection switch of the type mentioned in the introduction, that prevents the known disadvantages and can be easily, quickly and flexibly adapted to specified usage requirements, and allows a simple and uncomplicated connection, whereby any additional components must be made as compact as possible. Furthermore, it is the task of a switch device, especially a fault current protection switch, above all a mains voltage-independent protection switch, to indicate which additional possibilities one has for assessment or classification of a fault current and thereby also with unusual fault currents safely triggers and thereby avoids far-reaching fault trips.

According to the invention, this is achieved with a switch device of the type mentioned in the introduction through the fact that the switch device includes a test device and that the functional group of the test device, which includes a test line and a test key, is arranged in the base.

As a result, at least one electronic control and/or regulation module in the interior of the switch device can be quickly and easily arranged and/or removed, without it being necessary to separate the switch device from the connections. Through the holder in the interior of the switch device, the module or the holder for the module must be kept small and compact, as this must not be made touch-proof and must not have a separate insulating material housing. Through the integration of at least one electronic control and/or regulation module, the protection switch, especially the residual current protection switch, can quickly be adapted to specific requirements. Through the use of various electronic control and/or regulation modules, i.e. differently programmed electronic control and/or regulation modules, the capabilities of the protection switch can be expanded with additional functions that can contribute to more effectively monitoring and protecting a wiring area to be protected. Furthermore, it is thereby possible for mains voltage-independent residual current protection switches, as they are prescribed in many countries for many applications, to expand with mains voltage-dependent additional functions, but where the residual current protection switch retains its mains voltage-independent basic functions and thus for the application it is concerned with. a country to which it applies further applies as mains voltage-independent fault current protection switch.

When using the electronic control and/or regulation module in a socket, control and/or regulation modules with identical outer dimensions can be inserted into differently sized protection switch housings. Furthermore, it is thereby possible to arrange

<*>hardware modules in the socket, which above all brings production advantages. Through this, it is also possible to solder wires to the base, whereby the electronic control and/or regulation module can still be removed from the switch apparatus.

By arranging the function group for the test device in the base, which includes a test line and a test key, a space-saving structure is realized. When using the electronic control and/or regulation module, this is automatically connected to the test section and can e.g. verify whether the test for functional capacity was carried out.

According to another design of the invention, it may be the case that the first and second contacts comprise contact springs, pins, pressure and/or drag contacts. Through this, the electronic control and/or regulation module can be quickly, simply, safely and uncomplicatedly inserted into the base, i.e. the socket in the holder of the switch device.

In other designs of the invention, there may be a switch device where the housing is designed in two parts in the form of a lower part that takes up the functional groups and a cover-like upper part, according to claims 1 to 4, where the holder is arranged in the lower part of the housing. This gives easy access to the holder by removing the upper part.

A variant of the invention can consist in the upper part having an inspection window and/or a breakthrough. Through this, any indication means found on the electronic control and/or regulation module can be considered, i.e. becomes possible through access to a possible infrared interface or a data interface socket which is present on the electronic control and/or regulation module.

In this context, it may be that the inspection window and/or the breakthrough includes a cover-up. As a result, when the control and/or regulation module is not inserted, the free holder can be protected against illegal access and also against dirt.

According to another design of the invention, it may be the case that the switching device comprises an internal data bus. Through this, a data exchange between the electronic control and/or regulation module and internal sensors that exist or in that there is a bus interface in the switch device, such as perhaps an EIB, LON or LAN interface possible.

According to another design of the invention, it may be that the electronic control and/or regulation module comprises third contacts for wireless connection with a base and/or a holder. Through this, the conductive connection to the base and/or to a holder is secured.

In furtherance of the invention, it may be the case that the electronic control and/or regulation module is connected to at least one sensor arranged in the switch device, for example a temperature sensor and/or the diodes of a current converter's tertiary winding. Through this, other operating parameters can be taken into account during the release, i.e. stored or be transferred to an external control.

In this context, in the continuation of the invention, it may be the case that the electronic control and/or regulation module at least includes an analogue/digital converter. Through this, incoming measurement signals can be processed further digitally, which is both noise-proof and also opens up many possibilities for signal analysis.

In other designs of the invention, it may be that the electronic control and/or regulation module comprises at least one integrated switch circuit, preferably a microprocessor and/or microcontroller and/or digital signal processor and/or Programmable Gate Array (programmable gate). As a result, the various tasks for the electronic control and/or regulation module can be carried out quickly and efficiently.

A variant of the invention can consist in the electronic control and/or regulation module having a data interface, preferably infrared, wireless, bluetooth, GSM, internet. Through this, a simple programming or a simple readout of stored data possible.

According to another design of the invention, it may be the case that the electronic control and/or regulation module includes means for instructions, preferably LEDs. Through this, different operating states and perhaps different triggering reasons can be visualized in a simple way.

The invention can, in particular with an electronic control and/or regulation module, be used for a switch device, in particular for a residual current protection switch.

Thereby, it is a task to further design an electronic control and/or regulation module of the aforementioned type so that a switch device, especially a protection switch or residual current protection switch of the type mentioned in the introduction, can be easily, quickly and flexibly adapted to specified usage requirements. Furthermore, it is the task of an electronic control and/or regulation module to indicate which further options are available for assessment or classification of a fault current and thereby determine also unusual fault currents safely and thereby avoid far-reaching fault triggering.

This is achieved by the electronic control and/or regulation module for the cableless device in a holder in the switchgear and for control and/or regulation of functions, especially additional functions, preferably setting the nominal fault current, producing the current floating fault current, short-term delay of the fault current tripping by transient course, delay times that can be set for the fault current tripping, registration and processing of non-sinusoidal fault currents such as perhaps truncated half-waves and/or superimposed direct current components, registration of over- and/or under-voltage, determination of the power factor cos cp, adaptation of the trip limit value corresponding to the relevant cos cp, programming of the functions via an interface before and/or after the device in a switch device, exchange of data with other electronic control and/or regulation modules arranged in a switch device, the switch device is designed.

As a result, the electronic control and/or regulation module can be waived on very extensive investment-requiring houses or insulation precautions, by which it can be kept very compact. Through the device in the interior, further contact connection with the switch device is not affected.

Through the arrangement of such an electronic control and/or regulation module in a switch device, this can take over many different tasks for the switch device, which can be adapted beyond this. Through the cableless device, an electronic control and/or regulation module can be quickly and easily arranged in a switch device or be removed from such.

In the following, the invention is described by way of example with reference to the attached drawings, where the designs are shown. Here, Figure 1 shows a switch device according to the invention with an inserted electronic control and/or regulation module, in axonometric design, Figure 2 a switch device according to Figure 1 without an upper part, Figure 3 a switch device according to Figure 2 without a base and without an electronic control and/or regulation module , figure 4 the upper part of a switch device according to the invention according to figure 1, figure 5 a first design of a base, in axonometric representation, figure 6 another prospect of a base according to figure 5, figure 7 another prospect of a base according to figure 5, figure 8 another prospect of a socket according to figure 5, figure 9 an electronic control and/or regulation module suitable for insertion into a socket according to figures 5-8, figure 10 another prospect of an electronic control and/or regulation module according to figure 9, figure 11 a switch device according to the invention with a base according to figures 5-8 and an electronic control and/or regulation module according to figures 9 and 1 0, exploded view, figure 12 a second design of a plinth in axonometric presentation, figure 13 a second prospect of a plinth according to figure 12, figure 14 a second prospect of a plinth according to figure 12, figure 15 an electronic control and/or regulation module suitable for insertion into a socket according to Figures 12 to 14, Figure 16 another prospect of an electronic control and/or regulation module according to Figure 15, Figure 17 a switch device according to the invention with a socket according to Figures 12 to 14 and an electronic control and /or regulation module according to figures 15 and 16 in exploded view, figure 18 another prospect of a switch device according to figure 17, and figure 19 a block diagram for a switch device according to the invention.

Figures 1 to 18 show designs and parts of a switch device 1 according to the invention, in particular residual current protection switches, which comprise functional groups arranged in a housing 3 such as detection unit, release relay, switch lock 45, switch contacts 43 and also a test device 4, and also connection terminals on the input and output side with at least one holder 7 to at least an electronic control and/or regulation module 8 inserted in the holder 7 is preferably connected cable-free, to contacts 9 which are connected to at least one functional group and occasionally to the connection terminals on the input side and/or output side.

In the selected designs of switch devices 1 according to the invention, it may be that these, without inserted electronic control and/or regulation module 8, fulfill a predetermined number of basic functions, perhaps the functions of a simple residual current protection switch. As a result, mains voltage-independent residual current protection switches can be extended with many additional functions that make the operation of a network to be protected more efficient, where in the event of an interruption in the voltage supply to the electronic control and/or regulation module 8, the mains voltage-independent basic functions of the residual current protection switch are preserved in its entirety. Consequently, such a residual current protection switch with all its possibilities is also usable in areas where mains voltage independence for the release is required.

Figure 19 shows the block diagram of a selected design of a four-pole mains voltage-independent residual current protection switch with an electronic control and/or regulation module 8. The residual current protection switch thus has, for the conversion of the mains voltage-independent release, a permanent magnet release 46. Furthermore, the residual current protection switch comprises a total current converter 42, switch contacts 43 , working current release 44, switch lock 45, normally open contact 47 and a voltage supply 48 to the electronic control and/or regulation module 8. Due to the effect of the permanent magnet release 46 on the switch lock 45, the residual current protection switch when the electronic control and/or regulation module 8 is not inserted has mains voltage-independent basic functions. With the electronic control and/or regulation module 8 inserted, this release function takes over over the working release 44 which likewise acts on the switch lock 45. The opening contact 47 is opened, whereby the permanent magnet release 46 is deactivated. The electronic control and/or regulation module 8 is preferably supplied over all outer conductors and the neutral conductor over the voltage supply 48, so that even in the event of a conductor interruption, the functions of the electronic control and/or regulation module 8 are secured. When the electronic control and/or regulation module 8 is de-energized, the opening contact 47 closes and activates the release path over the permanent magnet release 46 and the residual current protection switch again works independent of mains voltage.

By using at least one electronic control and/or regulation module 8 in the holder 7 provided for this, the functions of a switch device 1 can be expanded. There may also be switch devices 1 which cannot function without an inserted electronic control and/or regulation module 8.

A switch device 1 according to the invention, as shown in Figures 1 to 4, and also 11, 17 and 18, comprises a housing 3 of insulating material which comprises an upper part 16 and a lower part 15, where the housing parts 15, 16 are connected by detachable connecting means , especially with screws, and the switch device can be opened by loosening the connecting means and lifting up the upper part 16, whereby access to the functional part of the switch device which is arranged in the lower part 15 is thereby provided. In the lower part 15 of the switch device 1, input and output terminals for connecting electrical conductors are arranged, whereby any number of electrical conductors can be present. Preferably, the design is for two or four electrical conductors, where for each there is a clamp for the neutral conductor and a h.h.v. three terminals for the live phases. The lower part of the switch device 1 further comprises a switch lock, operating element, detection unit, trigger unit, and optionally a test device 4, whereby the operating element 21 with attached upper part 16 protrudes from a breakthrough 17 on the upper part 16. The operating element 21 is mechanically connected to the switch lock.

The selected designs of a switch device 1 according to the invention are residual current protection switches.

Switch devices 1 according to the invention have a holder 7 for at least one electronic control and/or regulation module 8, where this can be arranged in such a way in the switch device 1 that it can be easily removed from the switch device 1 after the upper part 16 has been removed.

The electronic control and/or regulation module 8 is preferably arranged in a base 10, whereby the base 10 has first contacts 11, for cableless connection with the electronic control and/or regulation module 8 and second contacts 12 for preferably cableless connection with the contacts 9 connected with at least one function group and occasionally with the connection terminals on the input side and/or the output side.

The plinth 10 has an essentially frame-like basic shape with a first plinth surface 22 and a second plinth surface 23 (figure 18), and also external plinth side surfaces 24. The plinth has a module holder 25 with inner module holder walls 26, where the module holder 25 is designed to match the outer dimensions of the the electronic control and/or regulation module 8. It may be that the module holder 25 is locked on the second plinth surface 23 with a plinth base 27, as in the designs according to figures 12 to 14. There may also be designs without plinth bottom 27, as in the design according to the figures 5 to 8.1 the selected designs have the base 10 an L-shaped extension 28.

It may be that hardware components are arranged in the base 10, such as perhaps the functional group of the test device 4, which includes a test current line and a test key 13. Through this, the automated production is supported. Furthermore, in this way, an electronic control and/or regulation module 8 can document the operation of the test key 13.

In the lower part 15, there is a holder 7 for the base 10. Thereby, it can be the case that the base 10 is attached releasably to a part of the switch device 1, preferably stuck on or screwed on, by means of non-manufactured connecting means. Preferably, it is possible to attach the base 10 to the carrier 29 on the operating element 21. For this, there may be suitable means along an external base side surface 24, perhaps holding grooves, holes and/or bores. By attaching the base 10 to a part of the switch apparatus 1, a defined position for the base 10 can also be secured with the upper part 16 removed. This is above all an advantage of the automated production.

The base 10 is in contact, in the selected designs, via two contacts 12 which are preferably arranged on the outer base side surfaces 24 and also on the other base surface 23, preferably contact tabs or contact springs, electrical contacts 9, 30 on the switch roller 31, by means of which the connection until the connection terminals are created, preferably to the connection terminals on the output side, and thus to the current-carrying phase and the neutral conductor. In this way, the electronic control and/or regulation module 8 arranged in the base 10 is also supplied with energy, and also with data about the supply voltage or current. With the switch device 1 disconnected, the switch roller 31 is in a position where the electrical contacts 9, 30 do not rest on the other contacts 12, i.e. the contact tabs 37 on the base 10 and therefore the electronic control and/or regulation module 8 is also de-energized. It may be the case that the electronic control and/or regulation module 8 is supplied with energy in other ways, so that it is still in operation with the switch device 1 switched off.

In the selected designs, the other contacts 12 further comprise contact surfaces 38 which are arranged on the outer base side surfaces 24. The contact surfaces 38 are preferably designed as conductive surfaces arranged in grooves 32. These serve as contacts with components or sensors arranged in the switching device 1, such as perhaps the detection unit, release relay, a permanent magnet release, a working current release, temperature sensors and/or the diodes of a current converter tertiary winding. The connections to the sensor or to the sensors can thereby be designed cable-free via contact springs, pins, pressure and/or tow contacts 14, or by means of cables that are soldered on or stuck on the contact surfaces 38.

The module holder 25 in the base 10 has many first contacts 11 for contact for the electronic control and/or regulation module 8. The electronic control and/or regulation module 8 is only electrically connected via third contacts 40 which are preferably designed as contact springs, pins, pressure and/or towing contacts 14. A cable connection, above all a fixed soldered one, is not available. The first contacts 11 are, in a design shown in Figures 5 to 8, arranged on the inner module holder walls 26. Through the device on the side, the base 10 is easily manufactured. With the design according to Figures 12 to 14, the first contacts 11 are designed on the other the plinth surface. For contact with the first contacts 11, in this design there is a breakthrough 39 in the bottom of the base 27. Through the introduction of the third contacts 40 of the electronic control and/or regulation module 8 in the corresponding adapted equal breakthroughs 39, this comes into contact with the conductive first the contacts 11 on the second plinth surface 23. The first contacts 11 can also be designed in the interior of the plinth 10, between the plinth base 27 and the second plinth surface 23. The breakthroughs 39 can be designed both as through openings and also as openings without passage. With this design of the base 10, there are no electrically conductive surfaces available in the module holder 25 for assemblers. This increases security in the event of changes or replacement of the electronic control and/or regulation module 8, as there can be no contact with current-carrying conductors, and thus no damage.

The electronic control and/or regulation module 8 exists for the expansion and/or change of the functionality of the switch device 1, above all for residual current protection switches, and is therefore connected to the detection and/or release and/or test unit of the switch device, preferably above the first and second contacts 11, 12 to the base 10.

The electronic control and/or regulation module 8 is preferably designed in the form of a square with a right-angled base surface which includes a top surface 33 and a bottom surface 34, and also side surfaces 35. According to the invention, the electronic control and/or regulation module 8 can have any desired shape, but which should be designed to match the shape of a module holder 25. The electronic control and/or regulation module 8 has a number of electrically conductive third contacts 40 which can be preset for contact with the first contacts 11 in the base 10.

In the design according to Figures 9 to 1, the third contacts 40 are designed on the side surfaces 35 in the area of the bottom surface 34.

In the design according to figures 15 to 18, the third contacts 40 are designed as pin-shaped protrusions 41 which rise from the bottom surface 34.

The connection to the electronic control and/or regulation module 8 with the base or until the holder 7 is made pole-change-proof. Either in the form of an asymmetric basic form for the electronic control and/or regulation module 8, an asymmetric device or the third contacts 40 and/or through the presence of guides and projections.

It may also be the case that the electronic control and/or regulation module 8 without a base 10 is inserted directly into a switch device 1. In this case, the third contacts 40 of the electronic control and/or regulation module 8 are designed in the same way as the other contacts 12 in the base 10, and the electronic control and/or regulation module 8 make contact with the function groups of the switch device 1 without the base 10. The electronic control and/or regulation module 8 comprises an internal electronics that includes at least one of the functions: recording of data, storage of data, transfer of data, receipt of orders, receipt of work routines or program codes, execution of management and/or regulation tasks preferably on the basis of predefined routines, execution of connection tasks. All these functions could optionally be performed in analogue and/or digital technology.

In the selected design, the electronic control and/or regulation module 8 comprises at least one analog/digital converter to digitize incoming analog measurement values for the internal further processing. It may be that every third contact 40 configured as an input is assigned to a separate analog/digital converter, or that several measured value inputs are connected via a multiplexer on an analog/digital converter. For internal further processing of the measurement data, the electronic control and/or regulation module comprises at least an integrated circuit, preferably a microprocessor and/or microcontroller and/or digital signal processor and/or Programmable Gate Array. In addition, there are also storage modules for storing programs and/or measurement data.

An electronic control and/or regulation module 8 may be able to change the height of the permitted fault current amplitude, the fault current quality and also the nature of the tripping in the affected switch device 1. Through this, a standard switch device can be adapted to the relevant application or a switch device already integrated in a house installation in the event of changed conditions be adapted to these.

In addition to this, an electronic control and/or regulation module 8 extends the functionality of a switch device 1, in particular a residual current protection switch. It may be possible to adapt the values outside the normal norm values. Furthermore, there may be a short-term delay for the fault current tripping in the event of transient events (e.g. lightning strikes), in order to increase the possibility of managing an installation section and avoiding fault trips. There may be over delay times that can be set to coordinate several fault current protection switches selectively to each other, in order to increase the possibility of disposing of installation sections in the event of a fault.

Furthermore, it may be possible to expand the knowledge and processing of fault currents, perhaps through the knowledge of fault currents, their curve shape which deviates from pure sine oscillations, e.g. cut-off half-waves, through knowledge of fault currents superimposed from a direct current part and/or through knowledge of pure direct current fault currents.

Furthermore, there may be knowledge of over- or undervoltages and also about overcurrents.

It may be possible to determine the relevant power factor cos cp and to take this into account when determining the permitted fault currents. When there is a high capacitive load share, higher operating leakage currents to earth can be permitted, while at the personal end the ohmic share must be assessed significantly more critically.

In addition, it may be possible to record and process other measurement values from the switch device 1, such as perhaps temperature.

With the help of the digital signal processing, the shown applications for an electronic control and/or regulation module can be easily realized. Different methods can be used for this, perhaps the evaluation of the digital signal current with regard to asymmetry or stability, the division of the measured fault current into different frequency ranges by means of digital filters and the evaluation of fault currents according to their frequency behavior and/or the assessment of the measured and digitized the error current using transformation algorithms such as perhaps FFT, DCT or Wavelet transformation.

In the selected design, a switch device 1 according to the invention has the electronic control and/or regulation module 8 arranged in this, a data boundary section. This can serve both for the programming of the electronic control and/or regulation module 8 as well as for the selection of various data such as perhaps the height of the fault current at the moment, the nature of the fault current, operating status and also statistical data. Furthermore, it can be the case that several, preferably two, electronic control and/or regulation modules 8 arranged in the switch device 1 communicate by means of a data interface. Through this, e.g. a redundant system can be built up, or several, not necessarily identical, electronic control and/or regulation modules 8 can share the protection tasks between them. It may also be possible to connect the switch device 1 over the data interface, to separate the affected installation section from the network, and/or to connect it again. Selected data interfaces are infrared, wireless, bluetooth, GSM, internet or a serial or parallel wired interface. But there can also be data interfaces of any other kind, such as perhaps LAN, UMTS, USB, Firewire, EIB, LON, optical waveguide, RS-232. In particular, the integration into a residential building management system can exist, perhaps with a wireless system where the individual devices act as routers for the entire wireless building system and also forward data destined for other (end-user) end devices. There may also be internal data buses which, above all, by connecting the switch device to a cable-bound system for data exchange, transmit the data to at least one electronic control and/or regulation module 8 up to the bus interface, another electronic control and/or regulation module 8 or up to a bus controller which must not be arranged in the electronic control and/or regulation module 8.

It is possible to program at least one electronic control and/or regulation module 8 both before the device in the switch device 1 and also after the device in the switch device 1. It is also possible to reprogram the at least one electronic control and/or regulation module 8 at any time subsequently. It may also be the case that with several electronic control and/or regulation modules 8 in a switch device 1, there is only one external data interface which receives the data of all the electronic control and/or regulation modules 8 arranged in the switch device, and passes them on to these.

For receiving data using infrared, the electronic control and/or regulation module 8 in the selected designs has an infrared receiver 36.

The electronic control and/or regulation module 8 further comprises means for indicating 19 of the operating states which are preferably designed on the top surface 33. According to the invention, there may be a type of means for indicating 19, perhaps LCD indicators, LED 20 or mechanical indicating means. In the selected design, the means for the instruction preferably comprise five light-emitting diodes 20.

In the area of the electronic control and/or regulation module 8, there is a breakthrough or an inspection window 17 in the upper part 16 of the housing 3 which, when an electronic control and/or regulation module 8 is not inserted, can be closed by means of a cover 18.

Claims (12)

1. Switch device (1), in particular a residual current protection switch, comprising functional groups arranged in a housing (3), such as detection unit, release relay, switch lock (45), switch contacts (43) and also connection terminals on the input and output side, where at least one holder (7) for at least one electronic control and/or regulation module (8), which is inserted in the holder (7), preferably cable-free, is connected to contacts (9) which are connected to at least one function group and occasionally to the connection terminals on the input and /or the output side, and where a preferably frame-like base (10) for the electronic control and/or regulation module (8) is arranged in the holder (7), where the base (10) has first contacts (11) for cableless connection with the the electronic control and/or regulation module (8) and other contacts (12) for, preferably cableless, connection with the contacts (9) connected to at least one function group and occasionally with the connection terminals on the input the side and/or the output side, characterized in that the switch device includes a test device (4), and that the functional group for the test device (4) which includes a test current section and a test button (13) is arranged in the base (10). 2. Switch device (1) according to claim 1, characterized in that the first and second contacts (11, 12) comprise contact springs, pins, pressure and/or drag contacts. 3. Switch device (1), where the housing (3) is designed in two parts in the form of a lower part (15) which accommodates one of the functional groups and a cover-like upper part (16), according to the preceding claim, characterized in that the holder (7) is arranged in the lower part (15) of the housing (3). 4. Switch device (1) according to claim 3, characterized in that the upper part (16) has an inspection window and/or a breakthrough (17). 5. Switch device (1) according to claim 4, characterized in that the window and/or the opening (17) comprises a cover (18). 6. Switch device (1) according to the preceding claim, characterized by the internal data bus. 7. Switch device (1) according to preceding claim, characterized in that the electronic control and/or regulation module (8) comprises third contacts (40) for cableless connection with the base (10) and/or holder (7). 8. Switch device (1) according to the preceding claim, characterized in that the electronic control and/or regulation module (8) is connected to at least one sensor arranged in the switch device (1), for example a temperature sensor and/or the diodes for the tertiary winding of a current converter. 9. Switch device (1) according to the preceding claim, characterized in that the electronic control and/or regulation module (8) comprises at least an analog/digital converter. 10. Switch device (1) according to the preceding claim, characterized in that the electronic control and/or regulation module (8) comprises at least one integrated switch circuit, preferably a microprocessor and/or microcontroller and/or digital signal processor and/or Programmable Gate Array ( programmable port). 11. Switch device (1) according to preceding claim, characterized in that the electronic control and/or regulation module (8) has a data interface, preferably infrared, radio, bluetooth, GSM, internet. 12. Switch device (1) according to the preceding claim, characterized in that the electronic control and/or regulation module (8) comprises means for instructions (19), preferably LEDs (20).