DE60017709T2 - Arrangement for remote monitoring of Led lights - Google Patents

Description

AREA OF INVENTION

The The present invention relates to the electrical supply of light emitting loads, in particular light emitting diode (LED) lamps. In particular, the present invention is concerned with remote monitoring required by LED lamps, electrical circuits.

BACKGROUND THE INVENTION

light emitting diode (LED) lamps are becoming more and more at traffic lights for automobiles, Railway signal lights and other applications usual. Your low power consumption is an attractive feature, but the main reason for her popularity is her long life (100,000 hours) compared to conventional ones Incandescent lamps (5,000 Hours). Obviously allow These features significantly reduce maintenance costs.

at certain applications, such as railway signal lights, can, As experts in the field know, these lamps are for signaling for main routes and / or signaling used at level crossings become. Signals for level crossings are common in populated areas, such as intersections, arranged. A remote monitoring the LED bulbs on signals for Railway underway is therefore not required. On the other hand, signals for main lines can be used be installed in remote areas that are not simple Way are achievable. Remote monitoring to verify integrity the signal lamps is therefore a common one Method.

For lights, the with conventional lightbulbs The electrical integrity can be simple Way be determined. When the filament of the light bulb in a normal State is in, flows Current through the lamp according to ohms Law (I = V / R). Otherwise it flows when the filament is interrupted There is no current through the lamp and it should be replaced.

For LED lamps however, an LED current is controlled by a power supply. For an LED lamp and a light bulb, therefore, the current characteristics not equal. For an LED lamp, alternating current (AC: Engl .: alternative current) of a mains voltage and then rectified by means of a DC-DC (DC) converter, which also controls the LED current regulated, converted to an appropriate level. In the case of a LED error or a failure of another electrical component in the LED lamp Is it possible, that the power supply continues to current at the rated current value or close to it, even if the LEDs do not emit light. Systems for remote monitoring could Therefore, the LED lamp will recognize as working correctly if it is is not in truth. This situation is unacceptable because they are too dangerous Train operated lead and significant accidents can cause.

One Another problem, the LED lamps and their power supplies and control equipment is affected by electrical components causing residual stress differences to sustain after Power has been removed from the LED lamp. The resulting Characteristic is that an LED lamp will actually light up when the power applied to it becomes a first high level achieved while it will only be turned off when the power is a second reached lower level. The resulting problem exists in that, if one particular performance, for example, by others near Kable is induced, the LED lamp remain switched on could, even if they actually should be out. This could as well too dangerous Situations lead.

These Special features of LED lamps limit their widespread use in situations where she monitors remotely Need to become, such as in applications for the signaling of railway main lines.

in the The prior art discloses the patent application number WO 99/07186, which discloses a fuse breakdown circuit suitable for a device for monitoring is provided by traffic lights. This device puts in between the supply lines short-circuited when the output voltage at the LED load terminals exceeds a predetermined limit, which corresponds to a fault in the LED load. The short between leaves the supply lines to break through a fuse to a state of broken Filament (area of incandescent lamps) imitate.

In order to the fuse breakdown circuit is activated, the converter must however, functional so that the output voltage rises above the threshold. The invention hangs thus from the integrity of the converter to the fuse breakdown to effect.

Also known in the art is French Patent Application No. 2,724,749, which discloses a traffic light monitoring apparatus. This device has a power cut-off device to remove the LED load when a means for detecting current determines that the current through the LED load drops below a predetermined level to mimic a broken filament condition. Again, in order for the fuse breakdown circuitry to be activated, the converter must be functional as the fuse breakdown circuitry is activated when the current flowing through the LED load is lower than a predetermined threshold for a minimum amount of time.

In Both of the above-described patent applications may provide the breakdown protection circuitry not be activated if the converter is damaged and the supply voltage (Vcc) can not generate.

Task of invention

A The object of the invention is therefore to make it possible that LED lamps are compatible with remote detection systems, the for monitoring from light bulbs are designed.

A Another object of the invention is an LED lamp circuit arrangement to provide the behavior of a light bulb in remote monitoring the LED lamp imitates.

Summary the invention

• a) eine Zeitgebereinrichtung, die auf die Spannung zwischen den ersten und zweiten Leitungen anspricht, um nach einer bestimmten Zeitdauer ein zeitrepräsentatives Signal zu erzeugen,
• b) eine Einrichtung, die mit der Zeitgebereinrichtung verbunden ist, um eine Erzeugung des zeitrepräsentativen Signals in Antwort auf den der LED zugeführten Strom zu verhindern, und
• c) eine Einrichtung, um einen Stromweg zwischen den ersten und zweiten Leitungen in Antwort auf das zeitrepräsentative Signal herzustellen,

wodurch, wenn kein Strom der LED zugeführt wird, der Stromweg aufgebaut wird und für den Kurzschluss zwischen ersten und zweiten Leitungen sorgt, der die Schutzsicherung zum Durchschlag bringt und einen offenen Schaltkreis einer fehlerhaften Glühlampe emuliert.In particular, according to the present invention, a fuse breakdown circuit is provided to short-circuit between first and second voltage and power supply lines to break down a protection fuse through which a current supplied to a light emitting diode (LED) flows through the first and second lines. wherein the fuse breakdown circuit is disposed on the input side of a transducer that powers the LED from the first and second lines, characterized in that the fuse breakdown circuit comprises:

• a) timing means responsive to the voltage between the first and second lines for generating a time-representative signal after a certain period of time,
• b) means connected to the timer means for preventing generation of the time-representative signal in response to the current supplied to the LED, and
• c) means for establishing a current path between the first and second lines in response to the time-representative signal,

whereby, if no current is supplied to the LED, the current path is established and provides for the short circuit between first and second lines, which breaks the protective fuse and emulates an open circuit of a defective incandescent lamp.

• a) einer Gleichrichtereinheit, die die Spannung und den Strom von der Quelle gleichrichtet und die gleichgerichtete Spannung und Strom ersten und zweiten Spannungs- und Stromzufuhrleitungen zuführt,
• b) einer Schutzsicherung, durch die der Strom von der Quelle der Gleichrichtereinheit zugeführt wird,
• c) einem Wandler der gleichgerichteten Spannung und Strom in die Gleichspannung und -strom, die der LED zugeführt werden,
• d) einem Sicherungsdurchschlagsschaltkreis nach Anspruch 2, um einen Kurzschluss zwischen den ersten und zweiten Spannungs- und Stromzufuhrleitungen herzustellen, um die Schutzsicherung zum Durchschlag zu bringen, und
• e) einer Steuerungseinrichtung des Wandlers in Antwort auf die gleichgerichtete Spannung auf den ersten und zweiten Leitungen.

Further, according to the present invention, a power supply unit responsive to a voltage and a current from a source for supplying a DC voltage and current to an LED is provided with:

• a) a rectifier unit which rectifies the voltage and current from the source and supplies the rectified voltage and current to first and second voltage and current supply lines,
• b) a protection fuse through which the current is supplied from the source of the rectifier unit,
• c) a converter of the rectified voltage and current into the DC voltage and current supplied to the LED,
• d) a fuse breakdown circuit according to claim 2, for making a short circuit between the first and second voltage and power supply lines to break the protective fuse, and
• e) a controller of the converter in response to the rectified voltage on the first and second lines.

The embodiments described herein the advantage that they limit the use of LED lamps in applications such as in applications for railway signal lights, enable, where a remote monitoring the lamps is required, with the advantageous features of a lower power consumption and a longer life.

Other Objects, advantages and features of the present invention in reading the following non-limiting description embodiments The same ersicht Lich, by way of example only with reference on the attached Drawings is provided.

SUMMARY THE DRAWINGS

In attached Drawings:

1 FIG. 10 is a schematic block diagram showing an LED lamp assembly including a shear breakdown circuit, an electroless filament detection circuit, and a turn-off voltage circuit; FIG.

2A FIG. 12 is a schematic electrical circuit diagram of a first embodiment of a fuse breakdown circuit according to the invention; FIG.

2 B FIG. 12 is a schematic electrical circuit diagram of a second embodiment of the shear breakdown circuit according to the invention; FIG.

3 Fig. 10 is a schematic electrical circuit diagram of a circuit for detecting an electroless filament which can be used in conjunction with a fuse breakdown circuit according to the present invention, and

4 FIG. 10 is a schematic electrical circuit diagram of a turn-off voltage circuit that may be used in conjunction with a fuse breakdown circuit according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to 1 becomes an AC (AC) mains voltage of an LED lamp 8th from a voltage and power source 10 over a line 11 fed. The AC mains voltage is using a functional block 12 , which has an EMI filter, overvoltage suppressor and input fuse, EMI (Electromagnetic Interference) filtered and suppressed for overvoltages. Then the mains voltage is through a rectifier 14 rectified and subsequently by a DC-DC converter 20 converted into a DC voltage. The DC voltage from the converter 20 is on a wire 21 fed to an arrangement 22 to illuminate in series / parallel designed LEDs (light emitting diodes). LEDs are more generally referred to as light emitting loads in the present specification.

The current flowing through the arrangement 22 from flowing in series / parallel connected LEDs, is powered by a current sensor 100 detected. This current sensor 100 generates an LED current measurement signal 23 , that of a power factor control device 28 is supplied. The function of the power factor control device 28 consists of the DC-DC converter 20 over a line 27 to control, in turn, the DC current and voltage on the line 21 controls.

In the illustrated example, the array of serially / parallel connected LEDs is a plurality of subgroups 26 of five (5) series-connected light-emitting diodes 24 educated. Each subgroup 26 of series-connected light-emitting diodes 24 is connected in parallel to the arrangement 22 in series / parallel connected LEDs. A special feature is that the anodes of the first light-emitting diodes of the subgroups 26 connected to each other, the cathodes of the first light-emitting diodes of the subgroups 26 and the anodes of the second light emitting diodes of the subgroups 26 connected to each other, the cathodes of the second light-emitting diodes of the subgroups 26 and the anodes of the third light-emitting diodes of the subgroup 26 connected to each other, the cathodes of the third light-emitting diodes of the subgroups 26 and the anodes of fourth light-emitting diodes of the subgroups 26 connected to each other, the cathodes of the fourth light-emitting diodes of the subgroups 26 and the anodes of the fifth light-emitting diodes of the subgroups 26 are interconnected and the cathodes of the fifth light-emitting diodes of the subgroups 26 connected to each other. Of course, other types of arrangements with different numbers of LEDs are possible within the scope of the present invention.

Various Embodiments of the EMI Filter (Block 12 ), the surge suppressor (block 12 ), the input fuse (block 12 ), the rectifier 14 and the DD converter 20 can be used. These embodiments are known to those skilled in the art and, accordingly, are not further described in the present specification. Also, in a preferred embodiment of the invention, a Motorola MC33262P integrated circuit (IC) chip is used as a power factor control device 28 used. However, it is within the scope of the present invention to use other IC chips that are commercially available on the market or that will be available in the market in the future.

1 shows a fuse breakdown circuit 16 , a detection circuit 18 for a currentless filament and a turn-off voltage circuit 30 , These circuits will be described in more detail below.

Fuse blow-out circuit

Referring to 2A a first embodiment of the fuse breakdown circuit is shown and in whole by the reference numeral 16 specified. The fuse breakdown circuit 16 receives the rectified voltage from the output terminal 15 of the rectifier 14 at an entrance 48 , The fuse breakdown circuit 16 also includes a second entrance 49 to get from the current sensor 100 the LED current measurement signal 23 to obtain. As long as no LED current measurement signal 23 at the entrance 49 occurs is a FET (field effect transistor) transistor 42 off. While the transistor 42 is turned off, becomes a capacitor 34 about a resistance 31 and a diode 32 from the tension on the entrance 48 is fed, loaded. At the same time becomes a capacitor 41 about the resistance 31 , the diode 32 and a resistance 37 loaded. When the voltage across the capacitor 41 the breakdown voltage of a tens diode 40 reached, the anode via a resistor 47 connected to ground (while transistor 42 remains switched off), a double-sided silicon switch (or TRIAC) switches 38 a to a current to a trigger electrode 103 a thyristor 39 to thereby supply this thyristor 39 to trigger. The triggering of the thyristor 39 in a conductive state generates a short circuit between an output terminal 15 of the rectifier 14 (please refer 1 and 2A ) and a ground output terminal 101 of the same rectifier 14 ,

This short circuit effectively brings the input fuse of the function block 12 to breakdown, which opens the circuit. Detection of this open circuit indicates that the lamp is faulty, thereby emulating the open circuit of a faulty light bulb.

It should be noted that the sequence of events described above takes place only after a predetermined period of time (fuse breakdown time) has elapsed while that of the current sensor 100 no electricity is detected. This predetermined period of time is constant and depends on the values of the resistor 31 , a resistance 33 , a resistance 35 and the capacitor 34 from.

On the other hand, if an LED current measurement signal 23 the entrance 49 is supplied before the end of the above, predetermined period of time, this LED current signal 23 to the gate electrode 102 of the FET transistor 42 about a resistance 43 applied to this transistor 42 turn. The capacitor 41 then discharges via a resistor 36 and the source / drain junction of the transistor 42 to the mass 101 , Accordingly, the capacitor 41 never fully charged, the breakdown voltage of the tens diode 40 never reached and no short circuit will be between the terminals 15 and 101 of the rectifier 14 generated. Then the input fuse of the function block remains 12 unharmed.

Referring to 2 B a second embodiment of the fuse breakdown circuit is shown and further with the reference numeral 16 specified. Again, the fuse breakdown circuit includes 16 the entrance 48 to the rectified voltage from the terminal 15 of the rectifier 14 to recieve. The fuse breakdown circuit 16 also includes the second entrance 49 containing the LED current measurement signal 23 from the current sensor 100 receives ( 1 ). As long as no LED power signal 23 at the entrance 49 occurs, is the FET transistor 42 off. When the transistor 42 is turned off, the capacitor becomes 34 about the resistance 31 and the diode 32 from the tension that is the entrance 48 is fed, loaded. When the voltage across the capacitor 34 the breakdown voltage of the tens diode 44 reached, the tens diode begins 44 (while the transistor 42 remains switched off) to carry electricity. A current then becomes the base of a PNP transistor 45 about the resistance 31 , the diode 32 and the tens diode 44 fed to this transistor 45 turn. The collector / emitter connection of the transistor is switched on 45 conductive to a current of the gate electrode of a FET transistor 46 supply. This turns on the FET transistor 46 on to make a short circuit between the output terminals 15 and 101 of the rectifier 14 via the source / drain connection of the FET transistor 46 manufacture. As shown, both are the emitter of the transistor 45 as well as the gate electrode of the transistor 46 about a resistance 47 connected to ground.

This short circuit effectively affects the input fuse of the block 12 lead to breakdown, whereby the circuit is opened. A detection of this open circuit indicates that the LED lamp 8th is faulty, whereby the open circuit of a faulty incandescent lamp is emulated.

It should be noted that the sequence of the above-described operations will take place only after a predetermined period of time (fuse breakdown time) has elapsed while no LED current measurement signal has expired 23 at the entrance 49 occurs. This predetermined period is a constant and depends on the values of the resistor 31 , the resistance 33 , the resistance 35 and the capacitor 34 from.

On the other hand, if the LED current measurement signal 23 at the entrance 49 occurs before the above predetermined time period has elapsed, this signal becomes the gate electrode 102 of the FET transistor 42 fed, causing the transistor 42 is turned on. This connects the positive terminal of the capacitor 34 about the resistance 36 with mass 101 to thereby the capacitor 34 to unload. In this case, the breakdown voltage of the tens diode becomes 44 never reached, the transistor becomes 45 remain disconnected, and will not short-circuit between the output terminals 15 and 101 of the rectifier 14 generated. The input fuse of block 12 remains intact in this case.

It should be noted that the "Siche For example, in one embodiment, the LED power-up time is approximately 100 msec. It is only to be noted that the "LED power-up time" is the time between turning on the LED lamp and the occurrence of the LED current measurement signal 23 at the entrance 49 is.

Detection circuit for electroless filaments

The detection circuit 18 for electroless filaments of 3 is used to simulate an incandescent lamp as it appears to a lamp test system. A lamp test is usually performed by applying a voltage pulse on the power supply line 11 is transmitted and checked that the current rises to a certain level within a certain period of time. This indicates the behavior of an incandescent lamp equivalent to a simple resistance.

An LED lamp uses a power supply that has a build-up time. If on the line 11 therefore, the current does not rise immediately, but only after the power factor control device 28 is on (for example, in one embodiment, after about 100 msec). The detection circuit 18 for electroless filaments of 3 solves this problem.

Once on the line 11 Power is supplied, the voltage drop across the resistor switches 51 which is between the output terminal 15 (Entrance 56 of the detection circuit 18 for electroless filaments) and a gate electrode 104 a FET transistor is connected, this transistor 53 one. This connects the resistance 52 between the output terminals 15 and 101 of the rectifier 14 ,

If on the line 11 for a period longer than the LED power-up time, power will be applied to the LED current measurement signal 23 an entrance 57 of the detection circuit 18 supplied for electroless filaments. This signal 23 gets to the base 105 a PNP transistor 54 attached to this transistor 54 turn on, causing the transistor 53 is turned off by its gate electrode 104 forcibly on earth 101 is placed. The detection circuit 18 for electroless filaments is thereby deactivated to the effect, the LED lamp 8th to be able to work normally. A bias resistor 50 and a tens diode 55 are in series between the entrance 56 and the base electrode 105 connected. The bias resistance 50 is also used for overvoltage protection.

The detection circuit 18 for electroless filaments also serves as a substitute for the fuse breakdown circuit 16 , If the fuse breakdown circuit 16 has failed (that is, it does not cause a short circuit to the input fuse of the block 12 to punch through, if it really should), the transistor would 53 stay on because no LED current measurement signal 23 at the entrance 57 would occur. The one about the resistance 52 withdrawn current is sufficiently high to block the input fuse after a certain period of time 12 to punch through. For example, in one embodiment of the invention, this period of time is a few minutes.

Abschaltspannungsschaltkreis

The shutdown voltage circuit 30 from 4 easily blocks the power factor controller 28 (please refer 1 ) when the input voltage on the line 11 of the circuit 30 is below a first predetermined trigger voltage.

The shutdown voltage circuit 30 includes an entrance 70 that with the voltage at the output terminal 15 of the rectifier 14 is supplied. The first predetermined trigger voltage 42 is determined by a voltage divider, the resistors 60 and 69 that covers between the entrance 70 the shutdown voltage circuit 30 and mass 101 connected in series. The first predetermined trigger voltage is established after a capacitor 68 about the resistance 60 and the diode 61 has been charged, ie after a predetermined period of time, the application of the voltage to the input 70 follows. This period of time is determined by the values of the resistors 60 . 69 and 107 and the capacitor 68 certainly.

The first predetermined trigger voltage 72 is applied to a gate electrode 106 a FET transistor 65 over the diode 61 created. When the first trigger voltage 72 the breakdown voltage of the gate electrode 106 of the FET transistor 65 reached, the transistor becomes 65 switched on.

The shutdown voltage circuit 30 includes a connection 71 that with a control terminal 29 the power factor control device 28 connected is. Before the transistor 65 is turned on, generates the power factor control device 28 a voltage drop across a resistor 62 with high impedance, thereby providing a second trigger voltage 73 which in turn generates a FET transistor 63 turns. This, in turn, creates a low impedance pathway that reduces the resistance 67 between the connection 29 the power factor control device 2 and mass 101 around summarizes. As long as the transistor 63 is on, the voltage is at the terminal 29 the power factor control device 28 lower than the voltage level required by the power factor controller 28 turn.

When the transistor 65 is turned off, this modifies the second trigger voltage 73 , causing the transistor 63 is switched off. The voltage at the connection 29 then reaches due to the high impedance value of the resistor 62 the level required to power factor control device 28 turn.

It should be noted that the LED lamp 8th does not turn on until the first trigger voltage 72 is achieved, and that once the lamp 8th Enlightened, this remains on until the voltage at the input 70 a first trigger voltage 72 generated under the trigger voltage of the transistor 65 is (breakdown voltage of the gate electrode 106 ).

Although the present disclosure includes specific types of transistors in the various circuits of the 2A . 2 B . 3 and 4 It should be kept in mind that these different types of transistors can be replaced or replaced by other available types of transistors.

Claims (13)

Fuse breakdown circuit ( 16 ) for establishing a short circuit between the first ( 15 ) and second ( 101 ) Voltage and power supply lines to provide a protection fuse ( 12 ) through which a light emitting diode (LED) (LED) ( 22 ) by means of the first ( 15 ) and second ( 101 ) Supplied current flows, wherein the fuse breakdown circuit at the input side of a transducer ( 20 ) is arranged, the LED ( 22 supplied from the first and second lines, characterized in that the fuse breakdown circuit ( 16 ) comprises: a) timing means responsive to the voltage between the first ( 15 ) and second ( 101 ) Lines to generate a time-representative signal after a certain period of time, b) means connected to the timer means for generating the time-representative signal in response to the LED ( 22 ) supply current, and c) a device to provide a current path between the first ( 15 ) and second ( 101 ) Lines in response to the time-representative signal, whereby when no current of the LED ( 22 ), the current path is established and for the short circuit between the first ( 15 ) and second ( 101 ) Lines are provided, the protection fuse ( 12 ) and emulates an open circuit of a faulty incandescent lamp. A fuse breakdown circuit according to claim 1, wherein the timer means comprises a resistor ( 31 ) and a capacitor ( 34 ) in series between the first ( 15 ) and second ( 101 ) Lines are connected, the resistance ( 31 ) has a predetermined resistance and the capacitor ( 34 ) has a predetermined capacitance value and a capacity charging period that depends on the predetermined resistance value and the predetermined capacitance value, the device connected to the timer device comprises a triggering circuit which is connected in parallel with the capacitor ( 41 ) and comprises a first controllable switching device which, in response to the LED ( 22 ) is closed to the Kondenstor ( 41 ), and the means for establishing a current path comprises a second controllable switch component which has a current path between the first ( 15 ) and second ( 101 ) Lines and in response to a predetermined voltage amplitude across the capacitance ( 41 ), whereby, in the absence of the LED ( 22 ) supplied current for a duration corresponding to the charging period of the capacitor ( 41 ), the predetermined voltage amplitude across the capacitor ( 41 ), thereby closing the second switch device, making the current path, and short-circuiting between the first ( 15 ) and second ( 101 ) To ensure the protection of the cables ( 12 ) and emulates an open circuit of a faulty incandescent lamp. Fuse breakdown circuit according to claim 1, wherein the first controllable switch component comprises a first transistor ( 42 ). Fuse breakdown circuit according to Claim 3, in which the resistor ( 31 ) is a first resistor, the capacitor ( 34 ) is a first capacitor and the second controllable switch component comprises: a) a second resistor ( 37 ) connected in series with a second capacitor ( 41 ), the second resistor ( 37 ) and the second capacitor ( 41 ) connected in series with each other, in parallel with the first capacitor ( 34 b) a semiconductor switch selected from the group consisting of a triac and a bilateral silicon switch ( 38 ), wherein the semiconductor switch is connected in parallel with the second capacitor ( 41 ), the semiconductor switch having first and second semiconductor switch electrodes and a trigger electrode, c) a zener diode ( 40 ) connected between the trigger electrode and one of the first and second semiconductor switch electrodes, the zener diode (10) 40 ) has a breakdown voltage value and to a voltage across the second capacitor ( 41 ), and d) a thyristor ( 39 ), which between the first ( 15 ) and second ( 101 ) Lines is connected and has a trigger electrode which is connected to one of the first and second semiconductor switch electrodes, whereby, in the absence of the LED ( 22 ) supplied current for a duration corresponding to the charging period of the capacitor ( 34 ), the predetermined voltage amplitude across the first capacitor ( 34 ) is reached, thereby to the second capacitor ( 41 ) over the second resistor ( 37 ) until the breakdown voltage value of the Zener diode ( 40 ) is reached and the semiconductor switch is triggered, thereby the thyristor ( 39 ), via the thyristor ( 39 ) make the current path and for the short circuit between the first ( 15 ) and second ( 101 ) To ensure the protection of the cables ( 12 ) and emulates an open circuit of a faulty incandescent lamp. A fuse breakdown circuit according to claim 4, further comprising a third resistor ( 47 ), which between the first ( 15 ) and second ( 101 ) Lines in series with the first resistor ( 31 ), the first capacitor ( 34 ) parallel to the third resistor ( 47 ) connected. Fuse breakdown circuit according to claim 3, wherein the second controllable switch component comprises: a) a second transistor ( 45 ) parallel to the first capacitor ( 34 ) is connected and has a control electrode, b) a zener diode ( 44 ) connected between the control electrode of the second transistor ( 45 ) and the capacitor ( 34 ), has a breakdown voltage and the voltage across the capacitor ( 34 ), and c) a third transistor ( 46 ), which between the first ( 15 ) and second ( 101 ) Lines and one of the second transistor ( 45 ) has activated control electrode, whereby, in the absence of the LED ( 22 ) supplied current for a duration corresponding to the charging period of the capacitor ( 34 ), the predetermined voltage amplitude across the capacitor ( 34 ) is reached in order subsequently to determine the breakdown voltage to the zener diode ( 44 ), the second transistor ( 45 ) and the third transistor ( 46 ) to establish the current path and for the short circuit between the first ( 15 ) and second ( 101 ) To ensure the protection of the cables ( 12 ) and emulates an open circuit of a faulty incandescent lamp. Fuse breakdown circuit according to Claim 6, in which the resistor ( 31 ) is a first resistor and the fuse breakdown circuit ( 16 ) further comprises a second resistor ( 33 ) connected in series with the first resistor ( 31 ) is connected, wherein the capacitor ( 34 ) in parallel with the second resistor ( 33 ) connected. Power supply unit that is responsive to a voltage and a current from a source ( 10 ) is responsive to a DC voltage and current of an LED ( 22 ), comprising: a) a rectifier unit ( 14 ), which measures the voltage and current from the source ( 10 ) rectifies and the rectified voltage and current first ( 15 ) and second ( 101 ) Supplies voltage and power supply lines, b) a protection fuse ( 12 ), through which the current from the source of the rectifier unit ( 14 ), c) a converter ( 20 ) of the rectified voltage and current into the DC voltage and current supplied to the LED ( 22 ), d) a fuse breakdown circuit ( 16 ) according to claim 2 for establishing a short circuit between the first ( 15 ) and second ( 101 ) Voltage and power supply lines to protect the fuse ( 12 ) and e) a control device ( 28 ) of the transducer in response to the rectified voltage at the first ( 15 ) and second ( 101 ) Cables. Power supply unit according to Claim 8, in which the first controllable switch component has a first transistor ( 42 ). Power supply unit according to claim 9, wherein the resistor ( 31 ) is a first resistor, the capacitor ( 34 ) is a first capacitor and the second controllable switch component comprises: a) a second resistor ( 37 ) connected in series with a second capacitor ( 41 ), the second resistor ( 37 ) and the second capacitor ( 41 ) connected in series with each other, in parallel with the first capacitor ( 34 b) a semiconductor switch selected from the group consisting of a triac and a bilateral silicon switch ( 38 ), wherein the semiconductor switch is connected in parallel with the second capacitor ( 41 ), wherein the semiconductor switch comprises first and second semiconductor switch electrodes and a trigger electrode, c) a zener diode ( 40 ) between the trigger electrode and one of the first and second semiconductors switch electrodes is connected, wherein the zener diode ( 40 ) has a breakdown voltage value and to a voltage across the second capacitor ( 41 ), and d) a thyristor ( 39 ), which between the first ( 15 ) and second ( 101 ) Lines is connected and has a trigger electrode which is connected to one of the first and second semiconductor switch electrodes, whereby, in the absence of the LED ( 22 ) supplied current for a duration corresponding to the charging period of the capacitor ( 34 ), the predetermined voltage amplitude across the first capacitor ( 34 ) is reached, thereby the second capacitor ( 41 ) over the second resistor ( 37 ) until the breakdown voltage value of the Zener diode ( 40 ) is reached and the semiconductor switch is triggered, thereby the thyristor ( 39 ), via the thyristor ( 39 ) make the current path and for the short circuit between the first ( 15 ) and second ( 101 ) To ensure the protection of the cables ( 12 ) and emulates an open circuit of a faulty incandescent lamp. A power supply unit according to claim 10, further comprising a third resistor ( 47 ), which between the first ( 15 ) and second ( 101 ) Lines in series with the first resistor ( 31 ), the first capacitor ( 34 ) parallel to the third resistor ( 47 ) connected. Power supply unit according to claim 9, wherein the second controllable switching device comprises: a) a second transistor ( 45 ) parallel to the capacitor ( 34 ) is connected and has a control electrode, b) a zener diode ( 44 ) connected between the control electrode of the second transistor ( 45 ) and the capacitor ( 34 ), has a breakdown voltage and the voltage across the capacitor ( 34 ), and c) a third transistor ( 46 ), which between the first ( 15 ) and second ( 101 ) Lines and one of the second transistor ( 45 ) has activated control electrode, whereby, in the absence of the LED ( 22 ) supplied current for a duration corresponding to the charging period of the capacitor ( 34 ), the predetermined voltage amplitude across the capacitor ( 34 ) is reached in order subsequently to determine the breakdown voltage to the zener diode ( 44 ), the second transistor ( 45 ) and the third transistor ( 46 ) to establish the current path and for the short circuit between the first ( 15 ) and second ( 101 ) To ensure the protection of the cables ( 12 ) and emulates an open circuit of a faulty incandescent lamp. Power supply unit according to claim 12, in which the resistor ( 31 ) is a first resistor and the fuse breakdown circuit ( 16 ) further comprises a second resistor ( 33 ) connected in series with the first resistor ( 31 ) is connected, wherein the capacitor ( 34 ) parallel to the second resistor ( 33 ) connected.