DE102021132327A1 - Circuit arrangement for avoiding overcurrent pulses in PWM operation of LED chains - Google Patents

Abstract

The invention relates to a circuit arrangement for avoiding overcurrent pulses in PWM operation of LED chains consisting of LEDs (LED1 to LEDx) and switches (SWITCH1 to SWITCHy) arranged electrically in parallel with the LEDs - with an electrical component (MOSFET) which has a first and has a second connection and a control connection,- wherein an ohmic resistance between the first and the second connection of the component (MOSFET) can be set via an electrical control signal at the control connection and- with a control circuit (C), which has a control signal output, a first input connection (LED_Output) and has a second input terminal and with which the electrical control signal for setting the resistance of the electrical component (MOSFET) can be generated,- the control signal output being connected to the control terminal of the electrical component (MOSFET),- the first input terminal (LED_Output ) is also connected to a supply voltage within the circuit arrangement or can be connected outside of the circuit arrangement,- the first connection of the component (MOSFET) being connectable to a second connection of the LED chain,- the second connection of the component (MOSFET) and the second Input terminal of the control circuit (C) are directly or indirectly connected to each other.

Description

The invention relates to a circuit arrangement for avoiding overcurrent pulses in PWM operation of LED chains, in particular LED chains in motor vehicle lights, for example turn signals.

It is known from the prior art to supply LED chains with a pulse width modulated current via DC/DC converters. The brightness of the LEDs can be adjusted using pulse width modulation (commonly referred to as PWM). In many applications, not all LEDs in an LED chain are now switched on. Rather, it is now common practice in some LED chains to switch on individual or all LEDs only at specific times in order to achieve a desired lighting effect. In order to enable the LEDs of the LED chain to be switched on and off individually, switches are arranged parallel to the LEDs, with which the LEDs can be short-circuited. In the documents DE 10 2019 115 517 A1 and DE 10 2018 104 672 B4 such circuit arrangements are disclosed.

Switching off LEDs of the LED chain can lead to overcurrent pulses that damage the switched-on LEDs. The overcurrent pulses can occur when the voltage at the output of the DC/DC converter is reduced by short-circuiting LEDs in the LED chain, thereby discharging the output capacitor of the DC/DC converter and increasing the current through the switched-on LEDs of the LED -chain drives.

An integrated circuit is known from the prior art with which these current pulses can be avoided. The integrated circuit is known under the name LITIX TLD7523-1 ES. With this solution, the output capacitor of the DC/DC converter is discharged to a value that limits the excess current to an acceptable value using a short-circuit switch integrated in the DC/DC converter. However, this periodic, rapid short-circuit discharge can lead to significant discharge currents in the control unit, which have a negative effect on electromagnetic interference emissions.

This is where the present invention comes in.

The present invention is based on the problem of proposing a circuit arrangement with which electromagnetic interference can be avoided or reduced during PWM operation of LED chains on a DC/DC converter when LEDs of the LED chain are switched off.

According to the invention, this object is achieved by a circuit arrangement having the features of claim 1 .

• - ein elektrisches Bauelement,
  • ◯ das einen ersten und einen zweiten Anschluss und einen Steueranschluss aufweist,
  • ◯ wobei ein ohmscher Widerstand zwischen dem ersten und dem zweiten Anschluss des Bauelementes über ein elektrisches Steuersignal an dem Steueranschluss einstellbar ist
• - und eine Steuerschaltung,
  • ◯ die einen Steuersignalausgang, einen ersten Eingangsanschluss und einen zweiten Eingangsanschluss hat und
  • ◯ mit der das elektrische Steuersignal zum Einstellen des Widerstands des elektrischen Bauelementes erzeugbar ist,
• - wobei der Steuersignalausgang mit dem Steueranschluss des elektrischen Bauelementes verbunden ist,
• - wobei der erste Eingangsanschluss mit einem ersten Anschluss der LED-Kette und einem Ausgang eines zur Stromversorgung der LED-Kette vorgesehenen DC/DC-Wandlers verbindbar ist, an eine Versorgungsspannung innerhalb der Schaltungsanordnung angeschlossen oder außerhalb der Schaltungsanordnung anschließbar ist,
• - wobei der erste Anschluss des Bauelementes mit einem zweiten Anschluss der LED-Kette verbindbar ist,
• - wobei der zweite Anschluss des Bauelementes und der zweite Eingangsanschluss der Steuerschaltung mittelbar oder unmittelbar miteinander verbunden sind.

A circuit arrangement according to the invention for avoiding overcurrent pulses in PWM operation of LED chains made of LEDs and switches arranged electrically in parallel with the LEDs has:

• - an electrical component,
  • ◯ which has a first and a second connection and a control connection,
  • ◯ wherein an ohmic resistance between the first and the second connection of the component can be set via an electrical control signal at the control connection
• - and a control circuit,
  • ◯ which has a control signal output, a first input terminal and a second input terminal and
  • ◯ with which the electrical control signal for setting the resistance of the electrical component can be generated,
• - wherein the control signal output is connected to the control terminal of the electrical component,
• - wherein the first input connection can be connected to a first connection of the LED chain and an output of a DC/DC converter provided for the power supply of the LED chain, can be connected to a supply voltage within the circuit arrangement or can be connected outside the circuit arrangement,
• - wherein the first connection of the component can be connected to a second connection of the LED chain,
• - Wherein the second connection of the component and the second input connection of the control circuit are directly or indirectly connected to one another.

The control circuit is capable of generating a control signal and making it available at the control signal output, with which the resistance in the electrical, controllable component is set. The control circuit can be set up in such a way that current through the component can be detected or a change in this current can be detected. If the current rises above a predetermined level, the controllable component is controlled in such a way that a higher electrical resistance is established between the first and the second connection of the controllable component. To detect the current, the control circuit on the use the first input terminal and the voltage present at the second input terminal. According to the invention, the control circuit can also have a connection for a reference potential. The reference potential can also be used to detect the current through the controllable component. According to one variant of the invention, the control circuit can be used to provide the electrical control signal at the control signal output as a function of a voltage between the connection for the reference potential and the second input connection.

The controllable component can be an FET, in particular a MOSFET. It is possible that the FET is an n-channel depletion type FET. The resistance between drain, the first terminal, and source, the second terminal, of the FET can be adjusted by the control signal at the gate.

According to the invention, the control signal that can be generated by the control circuit can be in the small-signal range of the electrical component. As a result, the resistance of the FET depends almost linearly on the voltage at the control signal input.

The control circuit of a circuit arrangement according to the invention can have a voltage divider made up of at least resistance components, which is connected on the one hand to the first input connection and on the other hand to the connection for the reference potential. A node, also referred to below as the first node for better differentiation from other nodes, of the voltage divider can be connected to the second input connection via a capacitor.

In addition to the resistance components, the voltage divider can have a transistor, in particular a pnp bipolar transistor, the base of which is connected indirectly via a resistance component or directly to the first input connection and to the reference potential. The collector is preferably connected indirectly via a resistance component or directly to the first input connection and the emitter is connected to the connection for the reference potential. A second node of the voltage divider can be connected to the base of the transistor.

The resistive device connected to the collector limits and defines the current through the transistor. Due to the defined current and the transfer characteristic of the transistor, an associated base-emitter voltage will be set, with the help of which an internal reference voltage is defined at the first node. The voltage at the first node can be set in particular as a function of the base-emitter voltage of this transistor. The second node may be connected to the first input terminal via a resistive component and to the first node via another resistive component.

The control circuit can have a temperature-sensitive component, in particular a thermistor. This can be a component of the voltage divider.

The first node can be connected indirectly via a resistance component or directly to the base of another transistor, in particular a pnp transistor, of the control circuit, the collector of which can be connected to the control signal connection and indirectly via a resistance component or directly to the first input connection and its emitter can be connected to the connection for the reference potential. If there is an increased current through the electrical component, this leads to the potential at the first node being raised. This increases the voltage between the base and the emitter of the other transistor, causing the collector-emitter path to become conductive. This changes the voltage at the collector and at the associated control signal output of the control circuit and the control signal input of the component whose electrical resistance between the first connection and the second connection is thereby increased.

The control circuit can have a zener diode, the cathode of which is connected to the control signal connection and the anode of which is connected to the connection for the reference potential. With this zener diode it is possible to protect the electrical component against overvoltage.

• 1 ein Schaltbild einer Anordnung aus einem DC/DC-Wandler, einer LED-Kette und einer erfindungsgemäßen Schaltungsanordnung.

The invention is explained in more detail below with reference to the attached drawings. It shows:

• 1 a circuit diagram of an arrangement of a DC / DC converter, an LED chain and a circuit arrangement according to the invention.

The circuit diagram shows a simplified DC/DC converter with a current source, an output coil L_OUT and an output capacitor C_OUT, which provides a current for operating the LED chain at an output LED_Output.

The LED chain consists of a series connection of parallel circuits, one or more LEDs LED1 to LEDx being connected in parallel to a switch SWITCH1 to SWITCHy in the parallel circuits. Through the switches SWITCH1 to SWITCHy, the LED LED1 to LEDx connected in parallel or the LEDs LED1 to LEDx connected in parallel to the switch SWITCH1 to SWITCHy can be short-circuited. For this purpose, the switches can be controlled by a controller, which is not shown.

A controllable electrical component MOSFET of the circuit arrangement according to the invention and a resistance component R_Shunt are arranged in series with the LED chain. A first terminal of the device is connected to the LED chain and a second terminal of the device is connected to the resistive device R_Shunt. A control signal input is connected to a control circuit C of the circuit arrangement according to the invention.

In the example shown, the electrical component is an n-channel MOSFET of the depletion type. The first terminal is the drain and the second terminal is the source of the MOSFET. The control signal input is the gate electrode of the MOSFET. However, it could also be another electrical component whose electrical resistance can be adjusted, for example a potentiometer with a drive.

If the switches SWITCH1 to SWITCHy remain unchanged for a long time, a voltage has developed across the output capacitor C_OUT of the DC/DC converter that corresponds to the voltage across the series connection of the LED chain, the controllable electrical component MOSFET and the resistance component R_Shunt.

If at least one of the previously opened or at least one previously opened switch Switch1 to Switchy is closed, the voltage across the LED chain changes. The voltage that is set at the output capacitor C_OUT due to the current flow through the LED chain is then suddenly higher than the voltage that drops across the LED chain, the electrical component MOSFET and the resistance component R_Shunt. This sudden voltage change causes the output capacitor to discharge through the LED string, the MOSFET device, and the R_Shunt resistive device. As a result, the current through the LED chain, the MOSFET component and the resistance component R_Shunt suddenly increases. A current pulse forms that can damage or destroy the LEDs in the LED chain.

The level of the current pulse is limited by the circuit arrangement according to the invention. For this purpose, the MOSFET component is controlled by the control circuit of the circuit arrangement according to the invention in such a way that the electrical resistance of the component is increased as a function of the current flowing through the component.

The control circuit can be designed in different ways. One possibility for a control circuit made up of discrete components is in 1 shown. However, other control circuits with the same function could also be used. The control circuit can also be designed as an integrated control circuit.

The control circuit has a control signal output which is connected to the control signal input of the MOSFET component. A control signal is provided at this control signal output, which control signal sets the electrical resistance of the component between the first connection and the second connection of the component.

The control signal is essentially generated by a transistor T1 of the control circuit. This transistor is connected to the collector via a resistive component to a first input terminal of the control circuit, which is connected to the output LED_Output of the DC/DC converter and in the 1 is also labeled LED_Output.

The emitter of the transistor T1 is connected to a connection for the reference potential (ground). The base of the transistor T1 is connected via a resistance component R6 and a capacitor C1 to a second input connection of the control circuit C, which is connected to the second connection of the controllable component MOSFET.

The node Ref. between the resistive component R6 and the capacitor C1 is also a node of a voltage divider formed from, in the example, resistive components R1, R2, R3, R4, R7, a transistor T2 and a thermistor NTC. The resistive components R1 and R7 have first terminals connected to the first input terminal LED_Output. The resistance component R1 is connected to the base of the transistor T2 with its second connection. The second connection of the resistance component R7 is connected to the collector of the transistor T2. The emitter of the transistor T2 is connected to the connection for the reference potential of the control circuit C.

A first connection of the resistance component R2 is also connected to the base of the second transistor T2 and thus also to the second connection of the resistance component R1. A second connection of the resistor Device R2 is connected to node Ref. between capacitor C1 and resistive device R6.

A first terminal of resistive device R3 is connected to node Ref. between capacitor C1, resistive device R6 and resistive device R2. A second connection of this resistance component R3 is connected to the connection for the reference potential via a parallel circuit made up of the NTC thermistor and the resistance component R4.

The voltage across this voltage divider defines a temperature dependent reference voltage that is slightly lower than the base-emitter voltage of transistor T1.

The transistor T2 is selected and connected in such a way that it always carries a current through the collector-emitter path. With this current, a reference voltage will be established between the base and the emitter, i.e. the voltage between the base and the reference potential.

A capacitor C2 between the input connection LED_Output and the connection for the reference potential buffers the voltage at the first input connection LED_Output, so that there is always approximately the same voltage compared to the reference potential.

A zener diode DZ parallel to the collector-emitter path of the transistor T1 t thus limits the voltage at the control signal output of the control circuit C and can thus protect the transistor T1 and also the controllable component MOSFET from overvoltages.

The voltage at the base is determined, among other things, by the voltage between the node Ref. and the reference potential. The voltage between the Ref node and the reference potential is also determined by the current through the resistive device R_Shunt and the voltage across the capacitor C1. When the entire system is in a steady state, the voltage between the node Ref. and the reference potential is set in such a way that the transistor T1 does not conduct any current across the collector-emitter path. Because of this and because no current flows through the resistance component R5, a voltage is present at the control signal output of the control circuit C, which voltage corresponds to the voltage across the zener diode DZ. Since this voltage is then also present at the control signal input of the controllable component MOSFET, the controllable component MOSFET is controlled in such a way that there is no resistance to the current from the first to the second connection.

So if the current driven by the DC/DC converter increases due to the short-circuiting of one of the LEDs LED1 to LEDx, this also leads to an increase in the current and thus the voltage across the resistance component R_Shunt and thus to an increase in voltage at the second input connection of the control circuit C. Since the capacitor C1 connected to the second input terminal does not react immediately to the voltage changes at the second input terminal, it initially maintains its voltage, thereby also increasing the voltage at node Ref. The voltage increase at node Ref then also affects the voltage between the base and emitter of transistor T1. The increase in the base-emitter voltage drives the transistor T1 in the small-signal range and allows a current to flow through the collector-emitter path, which was previously blocked. As a result, the voltage at the collector, which corresponds to the voltage at the control signal output of the control circuit C, drops. The falling voltage at the control signal output and thus at the control signal input of the controllable component MOSFET leads to the current between the first connection of the controllable component and the second connection of the controllable component being reduced. This increases the resistance and reduces the current through the LED chain. Although this cannot fundamentally prevent current pulses, they are limited in magnitude so effectively that there is no risk of destruction for the LEDs LED1 to LEDx.

After the output capacitor has discharged, the current through the LED string has settled back to normal levels. The voltage across the resistive component and hence the second input terminal and node Ref. As a result, the voltage at the control signal output of the control circuit and at the control signal input of the controllable component MOSFET is increased again by the transistor T1, as a result of which the resistance between the first connection and the second connection of the controllable component MOSFET decreases again until the component MOSFET is fully conductive again .

Reference List

DC/DC

DC/DC converter

1

Power source of the DC/DC converter

L_OUT

DC/DC converter output choke

C_OUT

DC/DC converter output capacitor

LED_OUTPUT

Output of the DC/DC converter/first input terminal of the control circuit

LED1 to LEDx

LEDs of the LED chain

SWITCH1 to SWITCHy

LED chain switch

C

control circuit

C1, C2

Control circuit capacitors

R1 to R7

Resistive components of the control circuit

T1, T2

Transistors of the control circuit

NTC

thermistor of the control circuit

dz

Zener diode of the control circuit

MOSFET

Controllable component

R_Shunt

resistor component

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102019115517 A1 [0002]
• DE 102018104672 B4 [0002]

Claims (9)

Circuit arrangement for avoiding overcurrent pulses in PWM operation of LED chains consisting of LEDs (LED1 to LEDx) and switches (SWITCH1 to SWITCHy) arranged electrically in parallel with the LEDs - With an electrical component (MOSFET), which has a first and a second terminal and a control terminal, - An ohmic resistance between the first and the second connection of the component (MOSFET) can be set via an electrical control signal at the control connection and - with a control circuit (C), which has a control signal output, a first input connection (LED_Output) and a second input connection and with which the electrical control signal for adjusting the resistance of the electrical component (MOSFET) can be generated, - wherein the control signal output is connected to the control terminal of the electrical component (MOSFET), - wherein the first input connection (LED_Output) is also connected to a supply voltage within the circuit arrangement or can be connected outside of the circuit arrangement, - wherein the first connection of the component (MOSFET) can be connected to a second connection of the LED chain, - Wherein the second connection of the component (MOSFET) and the second input connection of the control circuit (C) are directly or indirectly connected to one another. Circuit arrangement according to claim 1 , characterized in that the control circuit (C) has a connection for a reference potential. Circuit arrangement according to claim 1 or 2 , characterized in that the control circuit (C) has a temperature-sensitive component (NTC). Circuit arrangement according to one of Claims 1 until 3 , characterized in that the electrical component (MOSFET) is a FET, for example a MOSFET, in particular an n-channel FET of the depletion type. Circuit arrangement according to one of claims 2 until 4 , characterized in that the electrical control signal can be provided at the control signal output with the control circuit (C) as a function of a voltage between the connection for the reference potential and the second input connection. Circuit arrangement according to claim 5 , characterized in that the control signal that can be generated by the control circuit (C) is in the small-signal range of the electrical component (MOSFET). Circuit arrangement according to one of claims 2 until 6 , characterized in that the control circuit has a voltage divider at least made up of resistance components, which is connected on the one hand to the first input connection (LED_Output) and on the other hand to the connection for the reference potential, and that a node (Ref) of the voltage divider via a capacitor (C1) with connected to the second input port. Circuit arrangement according to claim 7 , characterized in that the node (Ref) is connected indirectly via a resistance component (R6) or directly to the base of a transistor (T1), in particular a pnp transistor, of the control circuit (C), whose collector is connected to the control signal terminal and indirectly via a resistor or is connected directly to the first input connection (LED_Output) and whose emitter is connected to the connection for the reference potential. Circuit arrangement according to one of Claims 1 until 8th , characterized in that the control circuit (C) has a zener diode (DZ) whose cathode is connected to the control signal connection and whose anode is connected to the connection for the reference potential.

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