CIRCUIT BREAKER

Abstract

A circuit breaker protecting an electric low-voltage circuit includes a housing with grid and load-side circuit connections. A mechanical isolating contact unit paired with load-side connections is series-connected to an electronic interruption unit paired with grid-side connections. A handle operating the isolating contact unit switches a contact opening function preventing current flow or closing function allowing current flow in the low-voltage circuit. Semiconductor-based switch elements of the electronic interruption unit switch to high-ohmic state preventing, or low-ohmic state allowing, current flow in the low-voltage circuit. A current sensor unit ascertains current level of the low-voltage circuit. A control unit is connected to the current sensor unit, isolating contact unit, and electronic interruption unit. Current flow in the low-voltage circuit is prevented upon exceeding current and/or current/time thresholds. An isolating contact unit handle sensor ascertains handle positions.

Claims

1-20. (canceled)

21. A circuit breaker device for protecting an electrical low-voltage circuit, the circuit breaker device comprising: a housing having network-side connections and load-side connections for the low-voltage circuit; an electronic interruption unit associated with said network-side connections, said electronic interruption unit having semiconductor-based switching elements; a mechanical isolating contact unit connected in series with said electronic interruption unit, said mechanical isolating contact unit being associated with said load-side connections, and said mechanical isolating contact unit having at least one contact; a handle configured to operate said mechanical isolating contact unit for switching opening of said at least one contact to avoid a current flow or closing of said at least one contact for a current flow in the low-voltage circuit; said semiconductor-based switching elements configured to be switched to a high-impedance state to avoid a current flow or a low-impedance state for a current flow in the low-voltage circuit; a current sensor unit for determining a current level of the low-voltage circuit; a control unit connected to said current sensor unit, to said mechanical isolating contact unit and to said electronic interruption unit, for initiating avoidance of a current flow in the low-voltage circuit upon exceeding at least one of current limit values or current-time limit values; and said mechanical isolating contact unit having a handle sensor for determining position information relating to said handle.

22. The circuit breaker device according to claim 21, wherein said handle sensor is connected to said control unit for providing said control unit with the position information relating to the position or movement of said handle and a closed or open state of said at least one contact to be provided by using said handle.

23. The circuit breaker device according to claim 21, wherein the position information from said handle sensor is processed in the circuit breaker device.

24. The circuit breaker device according to claim 21, wherein the position information is used to carry out functional checks of the circuit breaker device based on the position information.

25. The circuit breaker device according to claim 24, wherein: a voltage level across said electronic interruption unit is determined for the functional check of the circuit breaker device upon said at least one contact of said mechanical isolating contact unit being open and said electronic interruption unit having been switched to high impedance; and a first fault condition is present upon a first voltage threshold value being undershot, for at least one of preventing said electronic interruption unit from having a low impedance or preventing closing of said at least one contact.

26. The circuit breaker device according to claim 25, wherein: said electronic interruption unit is switched to a low-impedance state for a first period of time and the voltage level across said electronic interruption unit is determined, for the functional check of the circuit breaker device upon said at least one contact of said mechanical isolating contact unit being open and said electronic interruption unit having been switched to high impedance; and a second fault condition is present upon exceeding a second voltage threshold value, for at least one of preventing said electronic interruption unit from having a low impedance or preventing closing of said at least one contact.

27. The circuit breaker device according to claim 25, wherein closing of said at least one contact of said mechanical isolating contact unit is prevented upon a fault condition being present and no enable signal (enable) being emitted to said mechanical isolating contact unit.

28. The circuit breaker device according to claim 26, wherein: said electronic interruption unit is switched to a low-impedance state for a second period of time and the voltage level across said electronic interruption unit is determined, for the functional check of the circuit breaker device upon said at least one contact of said mechanical isolating contact unit being closed and said electronic interruption unit having been switched to high impedance; and upon exceeding a third voltage threshold value, a third fault condition at least one of prevents said electronic interruption unit from being switched to low impedance or initiates opening of said at least one contact.

29. The circuit breaker device according to claim 28, wherein said electronic interruption unit is switched to a low-impedance state upon an instantaneous value of a voltage between a network-side neutral conductor connection and a network-side phase conductor connection undershooting a fourth voltage threshold value.

30. The circuit breaker device according to claim 29, wherein: a voltage level across said electronic interruption unit is determined for the functional check of the circuit breaker device upon said at least one contact of said mechanical isolating contact unit being closed and said electronic interruption unit having been switched to low impedance; and upon exceeding a fifth voltage threshold value, a fourth fault condition at least one of initiates said electronic interruption unit having a high impedance or initiates opening of said at least one contact.

31. The circuit breaker device according to claim 30, wherein: said electronic interruption unit is switched to a high-impedance state for a third period of time and the voltage level across said electronic interruption unit is determined for the functional check of the circuit breaker device upon said at least one contact of said mechanical isolating contact unit being closed and said electronic interruption unit having been switched to low impedance; and upon undershooting a sixth voltage threshold value, a fifth fault condition at least one of initiates said electronic interruption unit having a high impedance or initiates opening of said at least one contact.

32. The circuit breaker device according to claim 31, wherein said electronic interruption unit is switched to a high-impedance state when the instantaneous voltage value between said network-side neutral conductor connection and said network-side phase conductor connection exceeds a seventh voltage threshold value and the instantaneous value of the voltage is at a maximum.

33. The circuit breaker device according to claim 22, wherein said mechanical isolating contact unit is configured to permit said position of said handle to differ from said closed or open state of said at least one contact.

34. The circuit breaker device according to claim 33, wherein said mechanical isolating contact unit has a position sensor for determining position information relating to said closed or open state of said at least one contact.

35. The circuit breaker device according to claim 21, wherein: said mechanical isolating contact unit is configured to permit said at least one contact to be opened, but not closed, by said control unit; and said mechanical isolating contact unit is configured to permit said handle to close said at least one contact only upon an enable signal being present.

36. The circuit breaker device according to claim 21, which further comprises further network-side and load-side phase conductor connections, and a series circuit of an electronic interruption unit and a contact of said mechanical isolating contact unit between each of said further network-side and load-side phase conductor connections, for a low-voltage three-phase AC circuit.

37. The circuit breaker device according to claim 21, wherein: upon said at least one contact of said mechanical isolating contact unit being closed and said electronic interruption unit having a low impedance, and: upon determining a current exceeding a first current value for a first time limit, said electronic interruption unit having a high impedance and said mechanical isolating contact unit remaining closed; upon determining a current exceeding a second current value for a second time limit, said electronic interruption unit having a high impedance and said mechanical isolating contact unit being opened; and upon determining a current exceeding a third current value, said electronic interruption unit having a high impedance and said mechanical isolating contact unit being opened.

38. The circuit breaker device according to claim 21, wherein said control unit has a microcontroller.

39. The circuit breaker device according to claim 21, wherein checking functions are started after closing of said at least one contact being captured by said handle sensor, and said electronic interruption unit being switched on in an event of a fault-free test.

40. A handle sensor for a mechanical isolating contact unit having a handle for a circuit breaker device for a low-voltage circuit according to claim 21.

Description

[0108] FIG. 1 shows a first basic illustration of a circuit breaker device,

[0109] FIG. 2 shows a second basic illustration of a circuit breaker device.

[0110] FIG. 1 shows an illustration of a circuit breaker device SG for protecting an electrical low-voltage circuit, in particular a low-voltage AC circuit, having a housing GEH, having:

[0111] network-side connections which comprise, in the example, a network-side neutral conductor connection NG and a network-side phase conductor connection LG, [0112] load-side connections which comprise, in the example, a load-side neutral conductor connection NL and a load-side phase conductor connection LL, [0113] the connections are provided for the low-voltage circuit; [0114] an energy source is usually connected to the network-side connections/the network side GRID, [0115] a consumer is usually connected to the load-side connections/the load side LOAD; [0116] an (in particular two-pole) mechanical isolating contact unit MK having a handle HH, load-side connection points APLL, APNL and network-side connection points APLG, APNG, wherein a load-side connection point APNL is provided for the neutral conductor, a load-side connection point APLL is provided for the phase conductor, a network-side connection point APNG is provided for the neutral conductor, and a network-side connection point APLG is provided for the phase conductor. The load-side connection points APNL, APLL are connected to the load-side neutral and phase conductor connections NL, LL, with the result that opening of contacts KKN, KKL in order to avoid a current flow or closing of the contacts for a current flow in the low-voltage circuit can be switched using the handle HH, in particular, [0117] an in particular single-pole electronic interruption unit EU (which is arranged, in particular, in the phase conductor in the case of a single-pole design), having a network-side connecting point EUG which is electrically connected to the network-side phase conductor connection LG, and [0118] a load-side connecting point EUL which is electrically connected to the network-side connection point APLG of the mechanical isolating contact unit MK, wherein the electronic interruption unit EU has, by virtue of semiconductor-based switching elements (not illustrated), a high-impedance state of the switching elements in order to avoid a current flow or a low-impedance state of the switching elements for the current flow in the low-voltage circuit, or can be switched, [0119] a current sensor unit SI for determining the level of the current of the low-voltage circuit, which current sensor unit is arranged, in particular, in the current path of the phase conductor or phase conductor current path, [0120] a control unit SE which is connected to the current sensor unit SI, the mechanical isolating contact unit MK and the electronic interruption unit EU, wherein avoidance of a current flow in the low-voltage circuit is initiated if current limit values or/and current-time limit values are exceeded.

[0121] According to the invention, the mechanical isolating contact unit MK is arranged on the load side, and the electronic interruption unit EU is arranged, according to the invention, on the network side.

[0122] The network side GRID having the energy source is normally live. An electrical consumer is usually connected to the load side LOAD.

[0123] The mechanical isolating contact unit MK has a handle sensor for determining position information relating to the handle, in particular relating to a closed or open state of the at least one contact or the contacts KKN, KKL of the mechanical isolating contact unit MK that is aimed for by means of the handle. Information relating to the positional state of the handle HH is therefore available, in particular, for the control unit SE, with the result that there is information relating to whether a connected consumer is possibly intended to be supplied with energy, since the novel circuit breaker device is advantageously almost continuously supplied with energy.

[0124] The circuit breaker device can be configured in such a manner that the level of the voltage across the electronic interruption unit can advantageously be determined. That is to say, the level of a first voltage between the network-side connecting point EUG and the load-side connecting point EUL of the electronic interruption unit EU can be determined or is determined.

[0125] For this purpose, a first voltage sensor unit SU1 connected to the control unit SE is provided in the example according to FIG. 1 and determines the level of the voltage between the network-side connecting point EUG and the load-side connecting point EUL of the electronic interruption unit EU.

[0126] During the voltage measurement by the first voltage sensor unit SU1, the voltage across the series circuit of the electronic interruption unit EU and the current sensor SI can alternatively also be determined, as illustrated in FIG. 1.

[0127] The current sensor unit SI has a very low internal resistance, with the result that the determination of the level of the voltage is not impaired or is negligibly impaired.

[0128] A second voltage sensor unit SU2 which determines the level of the voltage between the network-side neutral conductor connection NG and the network-side phase conductor connection LG can be advantageously provided.

[0129] The first voltage sensor unit can also be replaced by using two voltage measurements (upstream of the electronic interruption unit and downstream of the electronic interruption unit). The voltage across the electronic interruption unit is determined by forming a difference.

[0130] A/the second voltage sensor unit SU2 connected to the control unit SE may be provided and determines the level of a second voltage between the network-side neutral conductor connection NG and the network-side phase conductor connection LG.

[0131] Furthermore, a third voltage sensor unit SU3 (not illustrated) connected to the control unit may be provided and determines the level of a third voltage between the network-side neutral conductor connection NG and the load-side connecting point EUL of the electronic interruption unit EU. The circuit breaker device is configured in such a manner that the level of a/the first voltage between the network-side connecting point EUG and the load-side connecting point EUL of the electronic interruption unit EU is determined from the difference between the second and third voltages.

[0132] A measurement impedance ZM may be connected between the network-side connection points APLG, APNG of the mechanical isolating contact unit MK. The measurement impedance ZM may be an electrical resistor or/and a capacitor, for example.

[0133] The measurement impedance may also be an inductor. In particular, the measurement impedance may be a series circuit or parallel circuit of a resistor or/and a capacitor or/and an inductor.

[0134] In the example according to FIG. 1, the electronic interruption unit EU has a single-pole design, in the phase conductor in the example. In this case, the network-side connection point APNG for the neutral conductor of the mechanical isolating contact unit MK is connected to the network-side neutral conductor connection NG of the housing GEH.

[0135] The circuit breaker device SG is advantageously configured in such a manner that the contacts of the mechanical isolating contact unit MK can be opened, but not closed, by the control unit SE, which is indicated by an arrow from the control unit SE to the mechanical isolating contact unit MK.

[0136] The mechanical isolating contact unit MK can be operated (by an operator or user) by means of the mechanical handle HH on the circuit breaker device SG in order to switch manual opening or closing of the contacts KKL, KKN. The mechanical handle HH can indicate the switching state (open or closed) of the contacts of the mechanical isolating contact unit MK on the circuit breaker device. However, the situation of the handle may also differ from the switching state of the contacts, for example if a so-called trip-free mechanism is used or the contacts are jammed.

[0137] In this case, for example, the mechanical isolating contact unit MK may advantageously have a position sensor for determining position information relating to the closed or open state of the at least one contact. A difference between the situation of the handle HH and the switching position of the contacts can therefore be determined. Measures for this case may be implemented. For example, sticky contacts, which are a problem for protecting the low-voltage circuit, May therefore be identified. As measures, the electronic interruption unit may come to have a high impedance, a message may be displayed on the circuit breaker device, a message may be emitted, for example to another circuit breaker device or/and monitoring or management system.

[0138] The mechanical isolating contact unit MK is advantageously configured in such a manner that (manual) closing of the contacts by means of the (mechanical) handle is possible only after an enable (enable), in particular an enable signal.

[0139] This is likewise indicated by the arrow from the control unit SE to the mechanical isolating contact unit MK. That is to say, the contacts KKL, KKN of the mechanical isolating contact unit MK may be closed (by the control unit) by means of the handle HH only when the enable or the enable signal is present. Although the handle HH can be actuated without the enable or the enable signal, the contacts cannot be closed (permanent slider contacts).

[0140] The circuit breaker device SG has an energy supply or power supply unit NT, for example a switched-mode power supply unit. In particular, the energy supply/power supply unit NT is provided for the control unit SE, which is indicated by a link between the energy supply/power supply unit NT and the control unit SE in FIG. 1. The energy supply/power supply unit NT is connected (on the other hand) to the network-side neutral conductor connection NG and the network-side phase conductor connection LG. A fuse SS, in particular a safety fuse, or a switch SCH (FIG. 2) may be advantageously provided in the link to the network-side neutral conductor connection NG (or/and phase conductor connection LG).

[0141] The power supply unit NT is normally constantly supplied with energy according to the invention. It is possibly protected by the fuse SS or can be switched off by means of the switch SCH.

[0142] Alternatively, the measurement impedance ZM may be connected to the network-side neutral conductor connection NG via the fuse SS. This advantageously makes it possible to implement a three-pole electronic unit EE (FIG. 2), for example in the form of a module, which has three connection points, one neutral conductor connection point and two phase conductor connection points. The electronic unit EE has, for example, the electronic interruption unit EU, the control unit SE, the energy supply NT (in particular including the fuse SS), the current sensor unit SI, optionally the first voltage sensor unit SU1 or/and optionally the second voltage sensor unit SU2.

[0143] The low-voltage circuit may be a three-phase AC circuit having one neutral conductor and three phase conductors. For this purpose, the circuit breaker device may be configured as a three-phase variant and may have, for example, further network-side and load-side phase conductor connections. In a similar manner, electronic interruption units according to the invention and (further) contacts of the mechanical isolating contact unit as well as current sensor units are respectively provided between the further network-side and load-side phase conductor connections. Voltage determinations (for example by means of first voltage sensor units) may also be provided.

[0144] High impedance is used to mean a state in which only a current of a negligible magnitude flows. In particular, high impedance is used to mean resistance values of greater than 1 kilohm, preferably greater than 10 kilohms, 100 kilohms, 1 megaohm, 10 megaohms, 100 megaohms, 1 gigaohm or greater.

[0145] Low impedance is used to mean a state in which the current value indicated on the circuit breaker device could flow. In particular, low impedance is used to mean resistance values of less than 10 ohms, preferably less than 1 ohm, 100 milliohms, 10 milliohms, 1 milliohm or less.

[0146] FIG. 2 shows a representation according to FIG. 1, with the difference that the circuit breaker device has a two-part design. It contains an electronic first part EPART, for example on a printed circuit board.

[0147] The first part EPART may have the control unit SE, the first voltage sensor unit SU1, the second voltage sensor unit SU2, the current sensor unit SI, the electronic interruption unit EU and the energy supply NT. The first part may also have the safety fuse SS, a switch SCH, the measurement impedance ZM, a temperature sensor TEM (in particular for the electronic interruption unit EU), a communication unit COM, and a display unit AE.

[0148] The first part EPART has only three connections: [0149] the network-side phase conductor connection LG, [0150] a connection for or to the network-side phase conductor connection point APLG of the mechanical isolating contact unit MK, [0151] a connection for a link to the network-side neutral conductor connection NG.

[0152] The communication unit COM can be a wireless communication unit, in particular.

[0153] The circuit breaker device contains a second part MPART, in particular a mechanical second part. The second part MPART may have the mechanical isolating contact unit MK with the handle sensor POS according to the invention for reporting the position of the handle to the control unit SE, the handle HH and an enabling unit FG. The second part may also have the (neutral conductor) link(s).

[0154] A differential current sensor ZCT, such as a summation current transformer, as is known, for example, from conventional fault-current circuit breakers, may also be provided.

[0155] Further units which are not described in any more detail May be provided.

[0156] A compact circuit breaker device according to the invention can be advantageously implemented by virtue of the two-part design.

[0157] The enabling unit/enabling function FG enables the actuation of the contacts of the mechanical isolating contact unit by means of the handle HH if there is an enable signal enable. That is to say, it is possible to close the contacts KKL, KKN (by the control unit SE) by means of the handle only when the enable signal enable is present. Otherwise, closing is not possible (permanent sliding of the handle HH). The contacts remain in the open situation/switching state. Furthermore, the enabling unit FG may open the contacts (second function of the enabling unit FG) if there is an opening signal OEF (from the control unit SE). The enabling unit/enabling function FG then acts as a tripping unit for opening the contacts of the mechanical isolating contact unit MK.

[0158] The current path via the mechanical isolating contact unit MK connected in series and the single-pole electronic interruption unit EU forms, when arranged in the phase conductor according to FIG. 1, a phase conductor path, that is to say a path for the phase conductor through the circuit breaker device SG (inside the housing). The neutral conductor is routed only via the mechanical isolating contact unit MK and is then a neutral conductor path, that is to say a path for the neutral conductor through the circuit breaker device SG (inside the housing).

[0159] It is also possible to provide a single-pole design of the circuit breaker device with only one mechanical contact, preferably in the phase conductor. The circuit breaker device then has, for example: [0160] (only) one load-side (phase conductor) connection LL [0161] a network-side phase conductor connection LG and a network-side neutral conductor connection NG.

[0162] The load-side neutral conductor connection is not provided in this case.

[0163] The position information can be advantageously used to carry out functional checks of the circuit breaker device. In particular, different checking functions can be carried out on the basis of the position information.

[0164] The following situation is considered, by way of example, below: [0165] nominal voltage or network voltage (for example 230 V AC) is applied to the network-side connection LG, NG or network side GRID or network connection of the circuit breaker device, [0166] a consumer or energy sink or load is connected to the load side LOAD of the circuit breaker device.

[0167] In the first step, the check in the OFF state of the electronic protection device is intended to be considered.

[0168] For this purpose: [0169] the mechanical isolating contact unit is open (contacts open)that is to say handle in the state for open contacts [0170] determination via the position sensor the electronic interruption unit is switched off (semiconductor-based switching elements have a high impedance) [0171] the control unit (including the controller unit) is active.

[0172] The electrical potential between the electronic interruption unit and the mechanical isolating contact unit is defined by the measurement impedance ZM and the impedance of the electronic interruption unit in the switched-off state (voltage divider).

[0173] The control unit can now switch on the semiconductor-based switching elements at any time (and therefore for a specific voltage division (depending on the instantaneous value of the voltage, the half-wave of the voltage)). The switching elements of the electronic interruption unit EU can hereby be tested by taking into account the polarity of the AC voltage.

[0174] The electronic interruption unit EU (or the electronic switch) is therefore switched on for a very short time (in the milliseconds range), for example. The measurement time is limited by the open contacts. If these are closed, this check is ended. The actuation of the handle for the (desired) closing of the contacts is determined according to the invention by the handle sensor POS. If the electronic interruption unit is functional, this can be determined by means of the (simultaneous) voltage measurement (for example first voltage sensor unit, second voltage sensor unit) and (subsequent) evaluation. For example, it is possible to determine, in the case of a defective semiconductor-based switching element, whether it always remains switched on (fault pattern: broken down) or always remains switched off (fault pattern: blown).

[0175] Two typical and common fault patterns are therefore covered.

[0176] If the check is fault-free, an enable to switch on the circuit breaker device, specifically the electronic interruption unit or the mechanical isolating contact unit, can be effected.

[0177] If the check is not fault-free, no enable to switch on the circuit breaker device will be effected, with the result that the outgoing circuit cannot be switched on and a dangerous state is therefore prevented.

[0178] The circuit breaker device is configured in such a manner that, when the contact(s) of the mechanical isolating contact unit MK is/are open and the electronic interruption unit EU has been switched to high impedance, the level of the voltage across the electronic interruption unit, that is to say the first voltage Ul, is determined. There is a first fault condition if a first voltage threshold value is undershot, with the result that the electronic interruption unit is prevented from coming to have a low impedance or/and closing 9 of the contact(s) is prevented. With regard to the mechanical isolating contact unit MK, an enable signal enable is not emitted from the control unit SE to the mechanical isolating contact unit MK, for example.

[0179] The circuit breaker device is advantageously configured in such a manner that closing of the contact(s) of the mechanical isolating contact unit MK is prevented when there is a fault condition. In particular, no enable signal (enable) is emitted to the mechanical isolating contact unit MK.

[0180] Another functional check may be that the contacts of the mechanical isolating contact unit are closed and the electronic interruption unit has a low impedance. The closed contact state (aimed for) by means of the handle is again determined using the handle sensor.

[0181] The circuit breaker device is configured in such a manner that, when the contact(s) of the mechanical isolating contact unit MK is/are closed and the electronic interruption unit EU has been switched to low impedance, the level of the voltage electronic the interruption unit is across determined. If a fifth voltage threshold value is exceeded, there is a fourth fault condition which initiates the electronic interruption unit coming to have a high impedance or/and initiates opening of the contact(s).

[0182] Furthermore, the circuit breaker device is configured in such a manner that, when the contact(s) of the mechanical isolating contact unit MK is/are closed and the electronic interruption unit EU has been switched to low impedance, the electronic interruption unit EU is switched to a high-impedance state for a third period of time and the level of the voltage across the electronic interruption unit is determined. If a sixth voltage threshold value is undershot, there is a fifth fault condition which initiates the electronic interruption unit coming to have a high impedance or/and initiates opening of the contact(s).

[0183] If the fifth or sixth fault condition is present, an opening signal OEF is sent from the control unit SE to the mechanical isolating contact unit MK in order to initiate opening of the contact(s). The control unit SE may also send a signal (not depicted) for coming to have a high impedance to the electronic interruption unit. The mechanical contact(s) is/are preferably opened shortly before the current zero crossing, with the result that the mechanical switching contacts can interrupt the current flow more easily.

[0184] The electronic interruption unit is advantageously switched to a high-impedance state when the instantaneous value of the voltage between the network-side neutral conductor connection and the network-side phase conductor connection exceeds a seventh voltage threshold value, in particular when the instantaneous value of the voltage is at a maximum.

[0185] A further functional check may be that the contact(s) of the mechanical isolating contact unit is/are closed and the electronic interruption unit has a high impedance. The closed contact state aimed for by means of the handle is again determined using the handle sensor.

[0186] The circuit breaker device is configured in such a manner that, when the contact(s) of the mechanical isolating contact unit MK is/are closed and the electronic interruption unit EU has been switched to high impedance, the electronic interruption unit EU is switched to a low-impedance state for a second period of time and the level of the voltage across the electronic interruption unit is then determined. If a third voltage threshold value is exceeded, there is a third fault condition which prevents the electronic interruption unit from being switched to low impedance or/and initiates opening of the contacts.

[0187] If the third fault condition is present, an opening signal OEF is sent from the control unit SE to the mechanical isolating contact unit MK in order to initiate opening of the contact(s). The at least one mechanical contact is preferably opened shortly before the current zero crossing, with the result that the mechanical switching contacts can interrupt the current flow more easily. Furthermore, the control unit SE can prevent or suppress a signal for the electronic interruption unit coming to have a low impedance.

[0188] The electronic interruption unit is advantageously switched to a low-impedance state when the instantaneous value of the voltage between the network-side neutral conductor connection and the network-side phase conductor connection undershoots a fourth voltage threshold value.

[0189] The switching-on time is advantageously selected, in the case of small voltage values (less than the fourth voltage threshold value), in order to minimize the resulting measurement current through the consumer/the energy sink/the load, and also to ensure personal protection. The fourth voltage threshold value may be, for example, (a maximum of) 50 V AC. That is to say, only safe (protective) extra-low voltages are used during switch-on.

[0190] A further functional check may be that the mechanical isolating contact unit is closed and the electronic interruption unit has a high impedance. Depending on the applied voltage polarity, the functionality of the switching elements can be checked in a similar manner by briefly switching on the electronic interruption unit or its semiconductor-based switching elements.

[0191] The closed contact state aimed for can again be determined using the handle sensor. The respective functional check can be ended during an operation of opening the handle.

[0192] The measurement impedance ZM should have a very high value (resistance or impedance value) in order to keep the losses low, for example a value of 1 MOhm, for example, in the case of a resistance. A value of 1 MOhm leads to losses of approximately 50 mW in a 230 V low-voltage circuit.

[0193] The level of the value of the measurement impedance should advantageously be such that the current through the measurement impedance is less than 1 mA for an applied network voltage (in the nominal range), with the result that the losses in the measurement impedance ZM are (negligibly) small. The (measurement) current is preferably less than 0.1 mA. For example, the measurement impedance should be greater than 100 kOhm, 500 kOhm, 1 MOhm, 2 MOhm, 3 MOhm, 1 MOhm, 5 MOhm or more.

[0194] Although the invention has been described and illustrated more specifically in detail by means of the exemplary embodiment, the invention is not restricted by the disclosed examples and other variations can be derived therefrom by a person skilled in the art without departing from the scope of protection of the invention.