DE102009000637A1 - Input-voltage switching device for use in fuse monitoring arrangement, has controlling device comprising transistor connected with another transistor, such that switching of latter transistor causes switching of former transistor - Google Patents

Abstract

The device (1) has a controlling device (5) controlling current flowing through a load (4), and a transistor (6) i.e. p-channel metal oxide semiconductor, controlling the controlling device based on a control-voltage (U2). The controlling device has another transistor (9) i.e. n-channel metal oxide semiconductor, connected with the former transistor, such that switching of the former transistor causes the switching of the latter transistor. The latter transistor maintains the switching condition of the former transistor till the control voltage falls below a threshold valve. Independent claims are also included for the following: (1) an arrangement for monitoring fuses (2) a method for switching an input-voltage lying at an input port to a load.

Description

The The invention relates to an apparatus and a method for switching an input voltage applied to an input port on a an output gate coupling load from a certain input voltage threshold.

The The invention further relates to an arrangement for monitoring fuses.

traditionally, comes to switching a voltage or input voltage to a load, z. B. an optocoupler for signaling a specific event, z. B. a failure of a monitored Fuse, a threshold with comparators for use. Disadvantageously needed Such a threshold with comparators own power supply or supply circuit for providing a supply voltage.

Therefore It is an object of the present invention to provide a device and a method of switching an input voltage to a load from a certain input voltage threshold to create, which manages without its own supply.

According to the invention this Asked task by a device having the features of the claim 1 and / or by an arrangement having the features of the claim 12 and / or by a method having the features of the claim 15 solved.

• – eine Einrichtung zum Steuern eines Stromflusses durch die Last;
• – einen ersten Transistor zum Steuern der Einrichtung in Abhängigkeit einer gegenüber der Eingangs-Spannung reduzierten Steuer-Spannung; und zwei am Eingangstor und mit einem Gate-Anschluss des ersten Transistor gekoppelte Widerstände zum Bereitstellen der reduzierten Steuer-Spannung;
• – wobei die Einrichtung zumindest einen zweiten Transistor aufweist, welcher mit dem ersten Transistor derart gekoppelt ist, dass ein Durchschalten des ersten Transistors in Abhängigkeit der reduzierten Steuer-Spannung ein Durchschalten des zweiten Transistors verursacht und der durchgeschaltete zweite Transistor einen durchgeschalteten Zustand des ersten Transistors aufrechterhält, bis die reduzierte Steuer-Spannung unter eine bestimmte Schwellwert-Spannung fällt.

Accordingly, a device is proposed for switching an input voltage applied to an input port to a load which can be coupled to an output port starting from a specific input voltage threshold value, which comprises:

• - means for controlling a flow of current through the load;
• - A first transistor for controlling the device in response to a comparison with the input voltage reduced control voltage; and two resistors coupled to the input port and to a gate terminal of the first transistor for providing the reduced control voltage;
• - wherein the device has at least one second transistor which is coupled to the first transistor such that a switching of the first transistor in response to the reduced control voltage causes a switching of the second transistor and the switched-through second transistor maintains a through-connected state of the first transistor until the reduced control voltage falls below a certain threshold voltage.

• – eine Messbrücken-Schaltung zur ausgangsseitigen Bereitstellung einer Messbrücken-Spannung, falls zumindest eine von der Messbrücken-Schaltung überwachte Sicherung ausfällt;
• – eine Gleichrichter-Einrichtung zum Gleichrichten der bereitgestellten Messbrücken-Spannung, welche an ihrem Ausgang einen Kondensator aufweist, der dazu eingerichtet ist, eine gleichgerichtete Messbrücken-Spannung ausgangsseitig bereitzustellen; und die wie oben erläuterte Vorrichtung zum Schalten der an dem Eingangstor anliegenden Eingangs-Spannung auf die an dem Ausgangstor koppelbare Last ab dem bestimmten Eingangs-Spannungs-Schwellwert, wobei die Vorrichtung eingangsseitig die gleichgerichtete Messbrücken-Spannung als Eingangs-Spannung empfängt.

Furthermore, an arrangement for monitoring a number of fuses is proposed, which comprises:

• A measurement bridge circuit for output provision of a measurement bridge voltage if at least one fuse monitored by the measurement bridge circuit fails;
• A rectifier means for rectifying the provided bridge bridge voltage having at its output a capacitor adapted to provide a rectified bridge voltage on the output side; and the device as described above for switching the input voltage applied to the input port to the load which can be coupled to the output port from the determined input voltage threshold value, the device receiving on the input side the rectified measuring bridge voltage as input voltage.

• – Bereitstellen einer Einrichtung zum Steuern eines Stromflusses durch die Last;
• – Steuern der Einrichtung in Abhängigkeit einer gegenüber der Eingangs-Spannung reduzierten Steuer-Spannung mittels eines ersten Transistors;
• – Bereitstellen von zwei an dem Eingangstor und mit einem Gate-Anschluss des ersten Transistor gekoppelten Widerständen zum Bereitstellen der reduzierten Steuer-Spannung; und
• – Ausstatten der Einrichtung mit zumindest einem zweiten Transistor, welcher mit dem ersten Transistor derart gekoppelt ist, dass ein Durchschalten des ersten Transistors in Abhängigkeit der reduzierten Steuer-Spannung ein Durchschalten des zweiten Transistors verursacht und der durchgeschaltete zweite Transistor einen durchgeschalteten Zustand des ersten Transistors aufrechterhält, bis die reduzierte Steuer-Spannung unter einen bestimmte Schwellwert-Spannung fällt.

Furthermore, a method for switching an input voltage applied to a device to a load which can be coupled to an output port of the device from a certain input voltage threshold value is proposed, comprising the following steps:

• - providing means for controlling a flow of current through the load;
• - Controlling the device in response to a relation to the input voltage reduced control voltage by means of a first transistor;
• Providing two resistors coupled to the input port and to a gate terminal of the first transistor for providing the reduced control voltage; and
• Providing the device with at least one second transistor, which is coupled to the first transistor such that a switching of the first transistor in response to the reduced control voltage causes a switching of the second transistor and the switched-through second transistor maintains a switched state of the first transistor until the reduced control voltage falls below a certain threshold voltage.

One Advantage of the present invention is that the inventive device for switching an input voltage to a load beyond a certain one Input Voltage Threshold without its own power supply or supply circuit.

Once the input voltage has a certain value, namely the input span has reached the threshold voltage, the current caused by the input voltage is switched immediately by means of the device for controlling the flow of current to the load, for example an optocoupler. The device only shuts off the current flow through the load when the input voltage or the control voltage falls below a certain threshold voltage.

The Operating principle of the present invention is based essentially insist that a turn-on of the first transistor in dependence the reduced control voltage turns on the second transistor causes and consequently the through-connected second transistor a through-connected State of the first transistor is maintained until the reduced control voltage a certain threshold falls below.

advantageous Refinements and developments of the invention will become apparent the dependent claims and the description with reference to the drawings.

According to one Another preferred embodiment, the first transistor is turned on, though the reduced control voltage is greater than a first transistor threshold voltage is.

According to one Another preferred embodiment is a third resistor such with the gate connection coupled to the second transistor that has a defined potential at the gate terminal of the second transistor is provided.

According to one Another preferred development, the device has exactly the second transistor, which for controlling the flow of current through the as resistively high load trained load is furnished and with the first transistor is coupled such that a switching through of the first transistor, a through-connection of the second transistor caused and the switched-through second transistor a through-connected State of the first transistor sustains until the control voltage fell below a certain threshold.

According to one Another preferred development, the device has the second Transistor and a third transistor for controlling the flow of current by the load, wherein the second and the third transistor with the first transistor are coupled such that a switching through of the first transistor in dependence the reduced control voltage turns on the second transistor and the third transistor causes and the second through Transistor keeps on turning on for the given period of time the control voltage has fallen below a certain threshold.

According to one Another preferred embodiment, the second transistor and the third transistor is configured in such a way that when switching through of the first transistor, the second transistor before the third transistor turns on.

According to one Another preferred embodiment, the second transistor and the third transistor of identical design, so that they are in the switching of the first transistor substantially simultaneously or timely switch through.

According to one Another preferred development are second transistor and the third transistor formed such that in the switching of the first transistor of the third transistor so shortly before the second Transistor turns on that the through state of the first transistor for the determined period of time by turning on the second transistor is ensured.

According to one Another preferred embodiment is the first transistor a PMOS transistor educated.

According to one Another preferred embodiment, the second transistor and the third transistor is in each case designed as an NMOS transistor.

According to one Another preferred development is the entrance gate between a first node and a second node formed. At the first Nodes are the first resistor and the source connector of the first one Transistor connected. At the second node are the second resistor, the third resistor, the source terminal of the second transistor and the source terminal of the third transistor.

According to one Another preferred development is the exit gate between formed the first node and a third node. The drain connection of the third transistor is connected to the third node and the load is connected between the first node and the third node.

According to one preferred embodiment of the arrangement is an optocoupler as Load coupled to the output port of the device. The optocoupler provides on the output side a pulse at the moment of switching through of the third transistor of the device.

According to one Another preferred embodiment of the arrangement, a signaling device is provided, which detected by the optocoupler pulses detected and the output side a signaling signal in response to a detection supplied Provides impulses.

Further becomes a feed circuit for self-feeding the signaling device the arrangement for monitoring the number of fuses proposed. The food circuit has at least two phase connection pairs, wherein a phase connection pair each suitable for coupling a fuse into a phase, a current source circuit and a parallel circuit of a capacitor and a Zener diode for providing the supply voltage to the signaling device or signaling circuit.

The at least two phase connection pairs are arranged such that the respective phase connection pair two phase connections to Coupling of the respective fuse has in the respective phase, wherein between the two phase terminals of the Phase connection pair at least two diodes so opposite are switched, that a current flow between the two phase connections of the Phase connection pair is prevented or prevented.

The Power source circuit is between the two diodes of the first Phase connection pair arranged and provides on the output side constant current independent ready from the voltage supplied by the phase terminal pairs.

The Parallel connection of the capacitor and the zener diode is between the power source circuit and the second phase connection pair. The parallel connection receives the constant current provided by the power source circuit, resulting in a constant voltage or supply voltage for feeding the signaling device is provided.

The Power source circuit has at least one power source, which consists of a series connection of an n-channel depletion transistor and a Resistance exists.

Preferably The power source circuit has a plurality of series connected ones Power sources, wherein the respective power source from a series circuit an n-channel depletion transistor and a resistor formed is.

The Invention will be described below with reference to the schematic figures specified embodiments explained in more detail. It demonstrate:

1 a schematic block diagram of an embodiment of an inventive device for switching an input voltage to a load from a certain input voltage threshold;

2 a schematic block diagram of an embodiment of an inventive arrangement for monitoring a number of fuses with the device according to 1 ; and

3 a schematic flow diagram of an embodiment of the inventive method for switching an input voltage to a load from a certain input voltage threshold.

In All figures are the same or functionally identical means and facilities - if otherwise stated - with provided the same reference numerals.

1 shows a schematic block diagram of an embodiment of a device according to the invention 1 for switching an input voltage U1 to a load 4 from a certain input voltage threshold.

The device 1 has at least one institution 5 for controlling a current flow I1 through the load 4 , a first transistor 6 , a first resistance 8th and a second resistor 11 ,

The first transistor 6 is set up to decorate 5 for controlling the flow of current 11 through the load 4 as a function of one with respect to the input voltage 1 to control reduced control voltage U2.

The first resistance 8th and the second resistance 11 are at the entrance gate 2 and with a gate connection 7 of the first transistor 6 coupled and configured to provide the reduced control voltage U2.

Furthermore, the device has 5 at least a second transistor 9 , The second transistor 9 is so with the first transistor 6 coupled, that a turning on of the first transistor 6 as a function of the reduced control voltage U2, a through-connection of the second transistor 9 caused and the through-connected second transistor 9 a switched state of the first transistor 6 maintains until the reduced control voltage falls below a certain threshold. A typical value for the lower threshold is z. B. 0.1 V.

The first transistor 6 switches in particular when the reduced control voltage U2 is greater than a first transistor threshold voltage of the first transistor 6 is. A typical value for the upper threshold is z. B. 2V.

Furthermore, the device has 1 preferably a third resistor 12 which is so connected to the gate terminal 13 of the second transistor 9 coupled is that a defined potential at the gate terminal 13 of the second transistor 9 is provided.

With regard to the design of the device 5 for controlling the current flow I1 through the load 4 the following alternatives are proposed:
As a first alternative, the device has exactly the second transistor 9 for controlling the current flow I1 through the load designed as a resistively high load 4 is set up and with the first transistor 6 is coupled such that a switching of the first transistor 6 a switching of the second transistor 9 caused and the through-connected second transistor 9 a switched state of the first transistor 6 , maintains until the reduced control voltage has fallen below a certain level.

As a second alternative (in 1 shown) has the device 5 the second transistor 9 and a third transistor 14 for controlling the current flow I1 through the load 4 wherein the second and the third transistor 9 . 14 with the first transistor 6 are coupled such that a switching of the first transistor 6 as a function of the reduced control voltage U2, a through-connection of the second transistor 9 and the third transistor 14 caused and the through-connected second transistor 9 the switched state of the first transistor 6 maintains until the reduced control voltage has fallen below a certain value.

Here are the second transistor 9 and the third transistor 14 as a first example configured such that in the switching of the first transistor 6 the second transistor 9 in front of the third transistor 14 turns on.

As a second example, the second transistor 9 and the third transistor 14 designed identical, so that these in the switching of the first transistor 6 essentially switch through at the same time or in a timely manner.

The third example is the second transistor 9 and the third transistor 14 formed such that in the switching of the first transistor 6 the third transistor 14 so close to the second transistor 9 switches through that the through-connected state of the first transistor 6 for the certain period of time by the turning on of the second transistor 9 is ensured.

For example, the first transistor 6 a PMOS transistor. Next, for example, the second transistor 9 and the third transistor 14 each formed as an NMOS transistor.

The entrance gate 2 the device 1 is between a first node 15 and a second node 16 educated. At the first node 15 is the second resistance 10 and the source connector 17 of the first transistor 6 connected. At the second node 16 is the first resistance 8th , the third resistance 12 , the source connector 18 of the second transistor 9 and the source connector 19 of the third transistor 14 connected.

The exit gate 3 is between the first node 15 and a third node 20 formed, with the drain connection 21 of the third transistor 14 with the third node 20 connected and the load 4 between the first node 15 and the third node 20 connected is. Weight 4 is designed for example as an optocoupler.

In 2 is a schematic block diagram of an embodiment of an inventive arrangement 22 to monitor a number of fuses F1-F3. The order 22 has the device 1 to 1 on.

The order 22 is set up to monitor a number of fuses F1-F3. The respective fuse F1-F3 is connected by means of a respective phase connection pair L1A, L1B; L2A, L2B; L3A, L3B coupled in the respective phase.

Next, the arrangement 22 a measuring bridge circuit 23 on. The measuring bridge circuit 23 on the output side provides a measuring bridge voltage U3, if at least one of the measuring bridge circuit 23 monitored fuses F1-F3 fails or blows.

Furthermore, the arrangement has 22 a rectifier device 24 that the measuring bridge circuit 23 is downstream. The rectifier device 24 is designed, for example, as a full-wave rectifier. The full-wave rectifier 24 is configured to rectify the provided measuring bridge circuit U3. Next, the full-wave rectifier 24 at its output to a capacitor C1, which is adapted to provide a rectified measuring bridge voltage U1 output side. The rectified measuring bridge circuit U1 serves the downstream device 1 according to 1 as input voltage.

The rectifier device 24 consists of the four diodes D1-D4.

Next, the arrangement 22 one of the device 1 downstream optocouplers 4 on that with the exit gate 3 the device 1 is coupled. The optocoupler 4 provides on the output side a pulse at the moment of turning on the third transistor 14 the device 1 or if one of the fuses F1-F3 fails or burns out.

For this purpose, the arrangement 22 further a signaling device 25 or signaling circuit on that of the optocoupler 4 detected pulses supplied and the output side, a signaling signal for signaling a failure of at least one fuse F1-F3 as a function of detection of delivered pulses provides.

For self-feeding of the signaling device 25 is preferably a feed circuit 26 intended.

The food circuit 26 is with at least two phase connection pairs 27 . 28 coupled.

The respective phase connection pair 27 . 28 has two phase connections L1A, L1B; L2A, L2B for coupling the respective fuse F1; F3 into the respective phase.

Next is the food circuit 26 configured such that between the two phase terminals L1A, L1B; L3A, L3B of the phase connection pair 27 . 28 in each case at least two diodes D5, D6; D7, D8 are switched so opposite that a current flow between the two phase terminals L1A, L1B; L3A, L3B is prevented.

According to the embodiment according to 2 are between the phase terminals L1A and L1B of the first phase terminal pair 27 the two diodes D5, D6 switched so opposite, that a current flow between the two phase terminals L1A and L1B of the first phase connection pair 27 is prevented.

Likewise, according to the embodiment of 2 between the two phase terminals L3A and L3B, the two diodes D7, D8 switched so opposite that a current flow between the two phase terminals L3A and L3B is prevented. Alternatively, the phase connection L1A can be interchanged with the phase connection L3A. Likewise, the phase connection L1B can be interchanged with the phase connection L3B. Further, instead of the phase terminals L1A and L1B, or instead of the phase terminals L3A and L3B, the phase terminals L2A and L2B may be used. Thus, in addition, the phase connections L2A and L2B can be provided via dedicated diodes (not in 2 ) are connected to the phases L1A and L1B in such a way that no current flow is possible between all said phase connections. Likewise, in addition, the phase terminals L2A and L2B may be provided via dedicated diodes (not in FIG 2 ) are connected to the phases L3A and L3B in such a way that no current flow is possible between all said phase connections.

Next, the feed circuit 26 a power source circuit 29 on which between the two diodes D5, D6 of the first phase connection pair 27 is coupled and the output side, a constant current 12 regardless of the means of the phase connection pairs 27 . 28 provided voltage.

Furthermore, the food circuit has 26 a parallel connection 30 from a capacitor C2 and a zener diode D9. The parallel connection 30 is between the power source circuit 29 and the second phase terminal pair 28 coupled. The parallel connection 30 from the capacitor C2 and the zener diode D9 is adapted to that of the current source circuit 29 provided constant current 12 to receive, whereby a constant voltage U4 for feeding the signaling device 25 is provided.

Preferably, the power source circuit 29 at least one current source, which consists of a series circuit of an n-channel depletion transistor 31 and a downstream resistor 32 consists. Alternatively, the power source circuit 29 also have a plurality of series-connected current sources.

3 shows a schematic flow diagram of an embodiment of the inventive method for switching an input voltage U1 to a load 4 from a certain input voltage threshold.

Hereinafter, the embodiment of the method according to the invention 3 with reference to the block diagram in FIG 1 explained. The inventive method according to 3 has the method steps S1 to S4:

Process step S1:

A device 1 is provided, which is set up, one at its entrance gate 2 applied input voltage U1 to one at its output gate 3 coupling load 4 if the input voltage U1 is greater than a certain input voltage threshold. Thereby the device becomes 1 with a device 5 for controlling a current flow I1 through the load 4 fitted.

Step S2:

The device 5 becomes in dependence of a relative to the input voltage U1 reduced control voltage U2 by means of a first transistor 6 the device 1 controlled.

Step S3:

There are two at the entrance gate 2 and with a gate connection 7 of the first transistor 6 coupled resistors 8th and 11 for providing the reduced control voltage U2 in the device 1 arranged.

Process step S4:

The device 5 is with at least a second transistor 9 fitted. The second transistor 9 is coupled to the first transistor such that a turning on of the first transistor 6 as a function of the reduced control voltage U2, a through-connection of the second transistor 9 caused and the through-connected second transistor 9 a switched state of the first transistor 6 maintains until the reduced control voltage falls below a certain threshold.

Even though the present invention described above with reference to the preferred embodiments it is not limited to that, but in many ways and modifiable.

Claims (15)

Contraption ( 1 ) for switching one at an entrance gate ( 2 ) applied input voltage (U1) to an output gate ( 3 ) coupling load ( 4 ) from a certain input voltage threshold, comprising: a) a device ( 5 ) for controlling a current flow ( 1 ) through the load ( 4 ); b) a first transistor ( 6 ) for controlling the device ( 5 ) in response to a relative to the input voltage (U1) reduced control voltage (U2); and c) two at the entrance gate ( 2 ) and with a gate connection ( 7 ) of the first transistor ( 6 ) coupled resistors ( 8th . 11 ) for providing the reduced control voltage (U2); d) where the facility ( 5 ) at least one second transistor ( 9 ), which is connected to the first transistor ( 6 ) is coupled such that switching through of the first transistor ( 6 ) in dependence of the reduced control voltage (U2), a through-connection of the second transistor ( 9 ) and the through-connected second transistor ( 9 ) a through-connected state of the first transistor ( 6 ) until the reduced control voltage falls below a certain threshold. Device according to claim 1, characterized in that the first transistor ( 6 ), when the reduced control voltage (U2) is greater than a first transistor threshold voltage of the first transistor ( 6 ). Device according to claim 1 or 2, characterized in that a third resistor ( 12 ) in such a way with the gate connection ( 13 ) of the second transistor ( 9 ) so that a defined potential at the gate terminal ( 13 ) of the second transistor ( 9 ). Device according to claim 1, 2 or 3, characterized in that the device ( 5 ) exactly the second transistor ( 9 ), which is used to control the flow of current ( 1 ) by the load designed as a resistively high load ( 4 ) and with the first transistor ( 6 ) is coupled such that switching through of the first transistor ( 6 ) a turn-on of the second transistor ( 9 ) and the through-connected second transistor ( 9 ) a through-connected state of the first transistor ( 6 ) maintains until the reduced control voltage falls below a certain threshold. Device according to Claim 1 or one of Claims 2 to 4, characterized in that the device ( 5 ) the second transistor ( 9 ) and a third transistor ( 14 ) for controlling the flow of current (I1) through the load ( 4 ), wherein the second and the third transistor ( 9 . 14 ) with the first transistor ( 6 ) are coupled in such a way that switching through of the first transistor ( 6 ) in dependence of the reduced control voltage (U2), a through-connection of the second transistor ( 9 ) and the third transistor ( 14 ) and the through-connected second transistor ( 9 ) the through-connected state of the first transistor ( 6 ) until the reduced control voltage has fallen below a certain threshold. Device according to Claim 5, characterized in that the second transistor ( 9 ) and the third transistor ( 14 ) in such a way that when the first transistor is switched on ( 6 ) the second transistor ( 9 ) in front of the third transistor ( 14 ) switches through. Device according to Claim 6, characterized in that the second transistor ( 9 ) and the third transistor ( 14 ) are of identical construction, so that they are switched on when the first transistor ( 6 ) pass through substantially simultaneously or in real time. Device according to Claim 5, characterized in that the second transistor ( 9 ) and the third transistor ( 14 ) are formed such that when the first transistor is turned on ( 6 ) the third transistor ( 14 ) so shortly before the second transistor ( 9 ) switches through that the through-connected state of the first transistor ( 6 ) for the determined period of time by the switching on of the second transistor ( 9 ) is ensured. Device according to Claim 5 or one of Claims 6 to 8, characterized in that the first transistor ( 6 ) is formed as a PMOS transistor and / or the second transistor ( 9 ) and the third transistor ( 14 ) are each formed as an NMOS transistor. Apparatus according to claim 9, characterized in that the entrance gate ( 2 ) between a first node ( 15 ) and a second node ( 16 ), wherein at the first node ( 15 ) the second resistor ( 10 ) and the source connection ( 17 ) of the first transistor ( 6 ) and at the second node ( 16 ) the first resistance ( 8th ), the third resistor ( 12 ), the source port ( 18 ) of the second transistor ( 9 ) and the source connection ( 19 ) of the third transistor ( 14 ) are connected. Device according to claim 10, characterized in that the exit gate ( 3 ) between the first node ( 15 ) and a third node ( 20 ), wherein the drain connection ( 21 ) of the third transistor ( 14 ) with the third node ( 20 ) and the load ( 4 ) between the first node ( 15 ) and the third node ( 20 ) connected is. Arrangement ( 22 ) for monitoring a number of fuses (F1-F3), comprising: a) a measuring bridge circuit ( 23 ) for the output side provision of a measuring bridge voltage (U3) if at least one of the measuring bridge circuit ( 23 ) monitored fuse (F1-F3) fails; b) a rectifier device ( 24 ) for rectifying the provided measuring bridge circuit (U3), which at its output a capacitor ( 21 ) configured to provide a rectified bridge voltage (U1) on the output side; and c) the device ( 1 ) according to claim 1 or one of claims 2 to 11, which receives on the input side the rectified measuring bridge circuit (U1) as an input voltage (U1). Arrangement according to claim 12, characterized in that an optocoupler as a load ( 4 ) with the exit gate ( 3 ) of the device ( 1 ), which has a pulse on the output side of the third transistor ( 14 ) of the device ( 1 ). Arrangement according to Claim 13, in which a signaling device ( 25 ) provided by the optocoupler ( 4 ) detected pulses and the output side provides a signaling signal in response to detection of delivered pulses. Method for switching a device to a device ( 1 ) applied input voltage (U1) to an output gate ( 3 ) of the device ( 1 ) coupling load ( 4 ) from a certain input voltage threshold, comprising the steps of: a) providing a device ( 5 ) for controlling a current flow (I1) through the load ( 4 ); b) controlling the facility ( 5 ) in dependence of a comparison with the input voltage (U1) reduced control voltage (U2) by means of a first transistor ( 6 ); c) providing two at an entrance gate ( 2 ) of the device ( 1 ) and with a gate connection ( 7 ) of the first transistor ( 6 ) coupled resistors ( 8th . 11 ) for providing the reduced control voltage (U2); and (d) equipping the facility ( 5 ) with at least one second transistor ( 9 ), which is connected to the first transistor ( 6 ) is coupled such that switching through of the first transistor ( 6 ) in dependence of the reduced control voltage (U2), a through-connection of the second transistor ( 9 ) and the through-connected second transistor ( 9 ) a through-connected state of the first transistor ( 6 ) until the reduced control voltage has fallen below a certain threshold.