DE202015106998U1 - Protection circuit for short-circuit protection for LED operating circuits - Google Patents

Abstract

Operating circuit (BS) for operating an LED track (L) with at least one LED, comprising - supply terminals, via which the operating circuit with a preferably constant regulated supply voltage (V) can be supplied, and - by a control circuit (SS) of the operating circuit ( BS) conductive / non-conductive controlled switching element (S), wherein the LED path (L) in series with the switching element (S) is connectable, characterized in that the operating circuit (BS) comprises a protection circuit (1) which is adapted thereto to detect a current through the switch element (S) when it is driven to the conductive state, and upon detection of a current exceeding a predetermined value, to spend the switch element (S) in the non-conducting state and to hold this non-conducting state until a reset event independent of the current through the switch element (S) takes place internally or externally.

Description

The invention relates to an operating circuit for the operation of at least one lamp and preferably of an LED track with at least one LED, and a method for operating such an operating circuit. The operating circuit may in particular be an LED converter, which preferably supplies the lighting means with a constantly regulated voltage.

According to the invention, a switch element is connected in series with the lighting means, which can be designed, in particular, as a FET or MOSFET transistor. This can be selectively switched on or off by a control circuit or switched to conductive and / or non-conductive. By driving the switch element by a control circuit, it is thus possible to achieve a dimming of the luminous means in that the duty cycle of a drive signal for the switch element is varied for a preferably cycled switching on and off of the switch element. In particular, the drive signal can be a pulse-width-modulated signal (PWM signal) which can be generated by the control circuit as a function of a dimming signal. The dimming signal can be supplied externally to the control unit. Depending on the duty cycle, which thus defines switch-on and switch-off durations, a dimming or a change in brightness on the lighting means can be effected, in particular, at a constant frequency.

The problem now is that in a fault, a short circuit can occur in parallel to the bulb. In this case, a very high current possibly flows through the switch element in its conducting state, which in consequence can lead to a very high thermal load on the switch element. In particular, this can lead to damage, impairment or destruction of the switch element.

The invention therefore proposes to provide a protective circuit in the operating circuit, which prevents the switch element from remaining in a switched-on or conducting state parallel to the lighting means when a short-circuit occurs, or being brought into or exchanging therewith.

The invention therefore provides an operating circuit, a luminaire and a method for operating a lighting operation circuit according to the independent claims. Further developments of the invention are the subject of the dependent claims.

In a first aspect, an operating circuit is provided for operating an LED track with at least one LED, having supply terminals, via which the operating circuit can be supplied with a preferably constant regulated supply voltage, and a switch element controlled by a control circuit of the operating circuit / nonconducting switch element, wherein the LED track in series with the switching element can be connected. The operating circuit has a protection circuit which is adapted to detect a current through the switch element, when it is driven into the conductive state, and upon detection of a current which exceeds a predetermined value, to spend the switch element in the non-conducting state and to hold this non-conductive state until a reset event independent of the current through the switch element occurs internally or externally.

The switch element can be connected in series with the LED path and preferably be a MOSFET transistor.

The reset event may be an interruption of the supply voltage, in particular for a predetermined period of time.

In series with the switch element, a measuring resistor can be interconnected. The protection circuit can detect the current at the measuring resistor or a signal representing this.

The protection circuit may, upon detection of the current exceeding the predetermined value, connect a potential of a gate terminal of the switch element to a ground potential and in particular short-circuit to the ground potential.

The protection circuit may comprise a latch circuit, preferably comprising two bipolar transistors. The protection circuit can be supplied by the supply voltage.

The latch circuit may be connected to the gate terminal of the switch element and the ground potential.

The protection circuit may hold the latch conductive until the reset event occurs.

The supply voltage may be a DC voltage of in particular 10-25, preferably 15 volts.

The control circuit may have a communication interface, a memory and / or at least one signaling means. The protection circuit may output a signal via the communication interface, to the memory and / or via the at least one signaling means upon detection of the current exceeding the predetermined value.

The control circuit can communicate the signal by wire and / or wireless, store and / or output visually and / or acoustically.

The control circuit can detect a state upon detection of the current that exceeds the predetermined value, and evaluate in particular with regard to its duration. The control circuit can control the switch element after a predetermined period of time. By this control, the switch element can be brought into the conductive state.

The operating circuit may be a constant voltage LED driver.

The control circuit can selectively control the switch element by means of a driver circuit conductive / non-conductive. The driver circuit can drive the switch element with a PWM signal, in particular with variable duty cycle, in particular depending on a dimming signal that can be fed to the control circuit.

In another aspect, a light is provided with an operating circuit as described herein.

In yet another aspect, there is provided a method of operating an operating circuit for an LED track having at least one LED, comprising the steps of: supplying the operating circuit via supply terminals with a preferably constantly regulated supply voltage, and driving a switch element into a conducting / non-conducting state a control circuit of the operating circuit. A protection circuit of the operating circuit detects a current through the switch element, when it is driven into the conductive state, and on detection of a current exceeding a predetermined value, the switch element spends in the non-conducting state and holds this non-conducting state, to internally or externally independent of the current through the switch element reset event occurs.

The invention will now be described with reference to the figures. Show it:

1 a circuit arrangement which illustrates the fault state (short circuit) addressed by the invention in parallel with the lighting means,

2 schematically essential components of an operating circuit according to the invention, and

3 an example is an SOA diagram for a switch element.

As in 1 is shown, a light source L, which is connected between two terminals LED + and LED- connected to the operating circuit, starting from a supply voltage V, in particular a DC voltage or rectified AC voltage supplied. The supply voltage V can be in particular 10-25 and preferably 15 volts. Parallel to the lamp L, an output capacitor CO is connected, which may have, for example, a capacity of 1.6 mF. In series with the light source L, a switch element S is further arranged, which can be controlled clocked by a control circuit SS.

If a short circuit now occurs parallel to the luminous means L, which means that the luminous means is short-circuited, and if the switch element S is turned on, then at least the current I _short provided by the output capacitor CO flows through the switch element in the direction of a ground potential, whereby the Switch element S can be damaged or destroyed.

According to the invention, there is thus provided a protection circuit as shown in FIG 2 is shown as part of the operating circuit BS. In 2 again is the circuit section 1 shown. However, other circuit components of the control circuit SS are shown in more detail.

As in the 2 shown parts of the operating _circuit BS is connected in series with the switch _element S, a measuring resistor R _shunt . At this measuring resistor R _shunt can be detected by the control unit SS, a current or a current reproducing (voltage) signal. The signal detected at the measuring resistor R _shunt then becomes a protection circuit 1 , in particular a latch or flip-flop circuit supplied.

If the signal at the measuring resistor R _{shunt exceeds} a predetermined threshold value, that is, the current through the switch _element S becomes unacceptably high, the protection circuit becomes 1 turned on, ie that preferably a gate terminal of the switch element S by the interconnection of the protection circuit 1 with at the ground or reference potential connected and thus shorted. Respectively, the potential of the gate terminal is connected to the ground or reference potential. As a result, on the one hand the switch element S is spent in the non-conductive state, on the other hand, a future displacement of the switch element S is prevented in the conductive state. The protection circuit 1 allows to keep this condition. A first transistor Q91 and a second transistor Q90 of the protection circuit 1 stay switched on. This state continues until a reset event occurs or occurs, ie the protection circuit 1 is reset. This can take place in that the supply voltage V, which may be independent of the current through the switch element, is switched off and on again, or interrupted for a predetermined period of time.

An advantage of the protection circuit 1 it is that a switching on of the switch element S is prevented, even if in the on or conductive state, the current through the switch element again has an admissible low value, ie in particular falls below the threshold.

The operating circuit BS is thus kept in the fault state caused by the short-circuit current Ishort until, in particular, a reset of the supply voltage V of the operating circuit BS or at least the protection circuit 1 he follows. The retention of the protection circuit 1 In this state, it can advantageously be exploited to the extent that it is possible to communicate in the state, for example, wirelessly or by wire. Thus, the information concerning the state can be stored in a memory connected to the control circuit SS and / or an optical / acoustic signaling by the control circuit SS can be initiated. For example, a communication with a central processing unit or other devices may be made to indicate an error condition. In order to make this possible, the operating circuit BS can have at least one communication interface for wireless and / or wired communication and, alternatively or additionally, can be connected to effectors which permit acoustic or optical signaling.

Furthermore, the control circuit SS can also evaluate the time profile so that a duration of the error state is detected. The control circuit SS can then trigger a reconnection of the switch element S after a predetermined period of time, for example in the range of seconds. The control circuit SS then determines whether the error state still exists. If after a renewed Leitendschaltung the switch element S again detects a current across the measuring resistor Rshunt, which is above the threshold, the control circuit SS switches the protection circuit 1 turn into the error state. However, if a current is detected below the threshold value, the control circuit SS can control the switch element S again with the drive signal, possibly depending on a dimming signal supplied to the control circuit SS, which reflects a desired intensity of a light emitted by the light source. Thus, short-circuiting short circuits or impermissibly high currents, which occur for example due to a short-time overvoltage, can be processed by the control circuit SS.

It should be noted that the error state can last longer. Since the operating circuit is in particular a constant-voltage LED driver, it is operated in the event of a short circuit as if no load or no lighting means L were connected to the operating circuit BS. A load on the components of the operating circuit BS is thus prevented.

With a view to 2 So are the two transistors of the protection circuit 1 that is, the first and second transistors Q90 and Q91, first in the non-conducting state (non-failure case). To trigger the protection circuit, first of all, the base-emitter voltage of the first transistor Q91, which is shown here as an NPN transistor, must be greater than or equal to the threshold voltage of the transistor Q91. When the base-emitter voltage of the first transistor Q91 is large enough, the collector current of the first transistor Q91 will flow and the second transistor Q90, exemplified as the PMP transistor, will be turned on, which further turns on the first transistor Q91. This state will stop until the supply voltage V of the protective circuit 1 is reset and in particular drops to 0V. This event can be triggered as a reset event, for example by restarting the operating circuit BS.

The activation of the first transistor Q91, ie its Leitendschaltung upon reaching the necessary base-emitter voltage is triggered by the measuring resistor Rshunt, so that the current through the switch element S, the protection circuit 1 activated. When the protection circuit 1 is activated, current flows from a collector of another transistor Q73 via a diode D90 to the ground potential, which means that no bias for the illustrated transistor circuit (push-pull stage) with the transistor Q70 and Q71 is present, and so the gate-source voltage of the switch element S remains low.

The diode D90 is provided to prevent a high level at the transistor circuit (push-pull stage) or at its output, since this could impair the function of the switch element S in that the switch element S would always be switched on, if the protection circuit 1 deactivated or the two transistors of the protection circuit Q90 and Q91 are not turned on.

The voltage across the resistor Rshunt is less than the minimum base-emitter voltage. If the diode D90 is short-circuited, the collector voltage of the second transistor Q90 of the protection circuit will take on the same form as the drive signal via the switch element, and in particular the PWM signal. If a short circuit occurs parallel to the load or parallel to the light source L, the protection circuit is switched on and the gate-source voltage will assume a low potential. The next positive drive pulse for the switch element S, the gate-source voltage of the switch element S again assumes a high level, whereby the switch element S is not turned on or off for a maximum of one period, after which the switch element S is turned on again.

As can be seen, the first transistor Q91 of the protection circuit is connected with its emitter to a potential-lower side of a first resistor R92. The higher potential side of the resistor R92 is connected to a first node K1, and above it to both the base of the first transistor Q91 and, via another resistor R93, to a higher side of the measuring resistor Rshunt. At the first node K1 is further the collector of the second transistor Q90 of the protection circuit 1 connected.

At the emitter of the second transistor Q90 of the protection circuit 1 the potential-lower side of a second resistor R91 and the cathode of the diode D90 are connected at a second node K2. The potential higher side of the second resistor R91 is on the one hand preferably with the supply voltage V and on the other hand with a third resistor R90 of the protection circuit 1 connected. Via the second resistor R91 and the third resistor R90, the emitter of the second transistor 90 is connected to the base of the second transistor 90 and to the collector of the first resistor Q91. More specifically, the lower potential side of the third resistor R90 is connected to a third node K3 to which the base of the second transistor Q90 and the collector of the first transistor Q91 are also connected.

The emitter of the first transistor Q91 is also connected to the lower potential side of the first resistor R92. The first and third resistors R90 and R92 are designed to hold the necessary holding currents of the transistors Q90, Q91. If the resistance values of the first and third resistors R90 and R92 are too low, the necessary base current can not be provided and the protection circuit can not be turned on.

If the third resistor R90 is bypassed or short-circuited, the base-emitter voltage of the second transistor Q90 will drop to 0 V and the protection circuit can not be switched on if there is a short circuit parallel to the lamp. Accordingly, the switch element S would still be damaged or destroyed in such a short circuit.

Next, the third resistor R90 serves the safe switching behavior of the protection circuit 1 although enough power can be provided by the second resistor R91 to drive the first transistor Q91 (NPN). The further resistor R93 is needed to keep the protection circuit in the activated state, ie in the state in which the gate potential of the switch element S with the Ground potential is connected. Otherwise, the protection circuit would turn off again, since the minimum base-emitter voltage of the first transistor Q91 can no longer be achieved.

How out 2 can be seen, between the anode of the diode D90 and the gate terminal of the switch element S, a part of the control circuit is shown, which in the following also as a driver circuit 2 is described.

The gate terminal of the switch element S is first connected via a resistor R73 to a ground potential. In addition, the gate terminal is connected to the transistor circuit via a resistor R72. The transistor circuit consists essentially of two transistors Q70 and Q71, which are formed as NPN and PMP transistors. At this time, the collector of the NPN transistor Q70 is connected through a resistor R71 to both the base of the NPN transistor Q70 and the base of the PNP transistor Q71. The collector of the PNP transistor Q71 is in turn connected to a ground potential, while the emitter of the PNP transistor Q71 is in turn connected to the resistor R72 and the emitter of the NPN transistor Q70. The collector of the NPN transistor Q70 is in turn preferably connected to the supply voltage V.

With the resistor R71, a NPN transistor Q73 is further connected to a fourth node K4, whose collector is connected to the fourth node K4 and whose emitter is connected to the ground potential. The base of the NPN transistor Q73 is connected via a resistor R77 to a signaling point. The signaling point is connected via a resistor R76 to the ground potential. The fourth node K4 in turn connects the transistor circuit and the resistor R71 to an anode of the diode D90.

Important for the invention is the dimensioning of the resistor Rshunt. For a quick shutdown by the protection circuit 1 To achieve this, a measuring resistance Rshunt with a high resistance value is needed. However, high resistance values for the measuring resistor Rshunt also lead to high losses at high output currents. For example, with an ideal resistance of R _95-ideal for the Rshunt of 15.5 mΩ, a power loss of 270 mW would result:

V _BE-Q91 is the base-emitter voltage of the first transistor Q91, while Imax _{-PWM-MOSFET represents} the maximum permissible current through the switch element S1. P _R95-ideal is then the power loss, which is determined by the resistance R _95-ideal and the maximum allowable current I _{LED max} by the light source. At the transistors of the protection circuit 1 and / or the driver circuit 2 they may be bipolar and / or field effect transistors.

Therefore, a compromise must be found, on the one hand to allow a quick shutdown with low losses. Possible safe operating modes can depend on the switch element S used from an exemplary in 3 shown SOA diagram (Safe Operating Areas diagram) are read. Here is a safe operating range at an initial temperature of 25 ° C for individual current pulses for a transistor IPD135N08N3 illustrated. The SOA curves show an allowable voltage, a current and time envelope for the operation of the switch element S as a MOSFET. The SOA curves thus show z. B. how long the switch element S can be operated at a voltage with a current pulse of a certain height permissible. I _{D represents} a drain current and V _DS a drain-source voltage again.

Also, different circuit line lengths should be considered for the circuit design since their impedance affects the short circuit behavior. For high impedance lines, it is possible for the threshold of the base-emitter voltage in the protection circuit 1 is not achieved. However, in this case, the output voltage drops to almost zero, which can be detected at the shunt resistor and whereby an undervoltage cut-off by the control circuit takes place.

An internal reset event can be triggered within the operating circuit BS and / or by the control circuit SS, z. B. after a predetermined time after the occurrence of the error condition. The control circuit may be equipped with a timer circuit, or z. B. have a capacity after unloading the reset event is triggered. An external reset event can be triggered outside the operating circuit BS and / or the control circuit SS, z. B. by a user and / or by pressing a power switch.

Claims (14)

Operating circuit (BS) for operating an LED track (L) with at least one LED, comprising - supply terminals, via which the operating circuit with a preferably constant regulated supply voltage (V) can be supplied, and - by a control circuit (SS) of the operating circuit ( BS) conductive / nonconducting controlled switch element (S), wherein the LED path (L) in series with the switching element (S) can be connected, characterized in that the operating circuit (BS) is a protection circuit ( 1 ) adapted to detect a current through the switch element (S) when it is driven to the conducting state, and upon detection of a current exceeding a predetermined value, the switch element (S) in the non-conducting state and maintain this non-conductive state until a reset event independent of the current through the switch element (S) occurs internally or externally. Operating circuit (BS) according to claim 1, wherein the switch element ( 1 ) is connected in series with the LED path (L) and is preferably a MOSFET transistor. Operating circuit (BS) according to claim 1 or 2, wherein the reset event is an interruption of the supply voltage (V), in particular for a predetermined period of time. Operating circuit (BS) according to one of the preceding claims, wherein in series with the switch element (S) a measuring resistor (Rshunt) is connected, and wherein the protective circuit ( 1 ) is adapted to detect the current at the measuring resistor (Rshunt) or a signal reproducing this. Operating circuit (BS) according to one of the preceding claims, wherein the protective circuit (BS) 1 ) is adapted, upon detection of the current exceeding the predetermined value, to connect a potential of a gate terminal of the switch element to a ground potential and in particular to short-circuit to the ground potential. Operating circuit (BS) according to one of the preceding claims, wherein the protective circuit (BS) 1 ) comprises a latch circuit, preferably comprising two bipolar transistors (Q90, Q91), and / or wherein the protection circuit ( 1 ) is supplied by the supply voltage. Operating circuit (BS) according to claim 6, wherein the latch circuit is connected to a gate terminal of the switch element (S) and a ground potential. Operating circuit (BS) according to one of the preceding claims, wherein the supply voltage (V) is a DC voltage of in particular 10-25, preferably 15 volts. Operating circuit (BS) according to one of the preceding claims, wherein the control circuit (SS) has or is operatively connected to a communication interface, a memory and / or at least one signaling means, and is arranged to detect, upon detection of the current exceeding the predetermined value, output a signal via the communication interface, to the memory and / or via the at least one signaling means. Operating circuit (BS) according to claim 11, wherein the control circuit (SS) is one adapted to communicate the signal wired and / or wireless, store and / or output visually and / or acoustically. Operating circuit (BS) according to one of the preceding claims, wherein the control circuit (SS) is adapted to detect a state upon detection of the current exceeding the predetermined value, and in particular to evaluate its duration, and wherein the control circuit (SS) to is set to control the switch element after a predetermined period of time. An operating circuit (BS) according to any one of the preceding claims, wherein the operating circuit (BS) is a constant voltage LED driver. Operating circuit according to one of the preceding claims, wherein the control circuit (SS) is adapted to operate the switch element (S) by means of a driver circuit (S). 2 ) selectively conduct conductive / non-conductive, wherein the driver circuit ( 2 ) is particularly adapted to the switch element ( 2 ) with a PWM signal in particular with variable duty cycle, in particular depending on a dimming signal, the control circuit (SS) can be fed. Luminaire with an operating circuit (BS) according to one of the preceding claims.

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