KR100628724B1 - A power supply circuit in a video display system and it's controlling method - Google Patents

Abstract

The present invention relates to a power supply circuit of a video display device and a control method thereof.

The present invention provides a power generation unit 10 for receiving a predetermined AC power supply voltage (AC) from the outside in the normal mode to generate a predetermined DC power supply voltage (Vo, Von, Vom) and to supply to each system; If a problem occurs in the system, the system is switched from the normal mode to the protection mode to suspend the DC power voltage (Vo, Vo, Vom) generation operation of the power generator 10, and when the problem is solved to protect the system In the power supply circuit of the image display device having a power control unit 20 for re-switching from the mode to the re-drive mode to resume the DC power voltage (Vo, Von, Vom) generation operation of the power generator 10, When the re-drive mode is repeatedly performed due to a system abnormality, the power control unit 20 switches the system from the re-drive mode to the latch-up mode so that the DC power voltages (Vo, Von, By completely stopping the Vom) generation operation, it is possible to prevent the fire that may occur when the re-start mode is repeated.

Video display device, power supply circuit, protection mode, restart mode, latchup mode

Description

A power supply circuit in a video display system and it's controlling method

1 is a block diagram illustrating a power supply circuit of a conventional video display device;

2 is a voltage and current waveform diagram of each part of a power supply circuit when an error occurs in a system;

3 is a block diagram illustrating a power supply circuit of an image display device according to the present invention;

4 is an operation flowchart of a first embodiment for implementing the present invention;

5 is an operational flowchart of a second embodiment for implementing the present invention.

 * Names of symbols for main parts of the drawings

10: power generation unit 20: power control unit

21: switching means 22: PWM signal generating unit

23: feedback voltage detector 24: overcurrent detector

25: overvoltage detector 26: temperature detector

27: power protection unit 28: power cut off

The present invention relates to a power supply circuit of an image display device.

More specifically, the power supply circuit of the video display device and the control method thereof are configured to completely switch off the power supply by switching the system to the latch-up mode in order to protect the system when the restart mode is repeatedly performed due to a system abnormality. It is about.

In general, the power circuit serves to properly supply the voltage required for each part of the image display device. The power circuit is smaller, lighter and more efficient than the linear power supply (SMPS). Related technologies are in a rapidly developing trend in recent years.

1 is a block diagram illustrating a switched mode power supply (SMPS) of an image display apparatus according to the related art.

As shown in FIG. 1, the switching power supply circuit is largely divided into a power generation unit 10 and a power supply control unit 20.

Here, the power generation unit 10 includes an input unit (D1, R1, C1) for converting a commercial AC voltage (AC) input from the outside into a DC voltage (Vi); A transformer 11 which receives a DC voltage Vi from one end of the primary winding from the input units D1, R1 and C1 and induces AC voltages Vs, Vsm and Vsn to the secondary winding; Outputs D2, C2, D3, C3, which convert AC voltages Vs, Vsm, Vsn induced from the secondary windings of the transformer 11 into DC voltages Vo, Vom, and Von and supply them to the respective systems. D4, C4).

In addition, the power control unit 20 is switched on / off by a PWM control signal to drive the transformer 11 to determine the magnitude of the DC voltage (Vo, Vo, Vom) generated by the power generation unit 20. Switching means 21 for adjusting; A PWM control signal generator 22 generating a PWM control signal by receiving a predetermined DC voltage Vo output from the power generator 10 and outputting the PWM control signal to the switching means 21; Compare the current measurement value, the voltage measurement value, and the temperature measurement value with each reference value, and if at least one measurement value is smaller than the reference value, output a detection signal of the first level, and if larger than the reference value, output a detection signal of the second level. The sensing unit 24, 25, 26 is comprised.

In the power supply circuit of the video display device having the above-described configuration, when the commercial AC power input from the outside is first supplied to the power generator 10, the transformer 11 is switched on or off by the switching means 21. When the energy stored in the primary winding is transferred to the secondary winding, and thus an AC voltage is induced on the secondary side of the transformer, the AC voltage is converted into a DC voltage and supplied to each part of the system.

At this time, the PWM signal generator 22 receiving the feedback of the predetermined DC voltage Vo output from the power generator 10 generates a PWM signal by the feedback voltage to switch on / off of the switching means 21. By controlling the voltage, the magnitudes of the DC voltages Vo, Vom, and Von generated from the power generator 10 are adjusted.

The overcurrent detector 24, the overvoltage detector 25, and the temperature detector 26 provided in the power controller 20 have reference values for determining whether the input values are normal.

In this case, the overcurrent detector 24, the overvoltage detector 25, and the temperature detector 26 output sensing signals of a first level when input values are less than or equal to a reference value, and sense signals of a second level when they are greater than or equal to a reference value. Outputs

The power supply circuit is generally provided with a power protection unit 27 to protect the circuit from abnormal system, there are large power protection unit according to the latch-up mode and power protection unit according to the restart mode.

When the detection signal of the second level is input, the power protection unit 27 according to the latchup mode switches the system from the normal mode to the latchup mode to completely stop the operation of the power generator 10.

For example, when an abnormality occurs in a circuit on the primary side or the secondary side of the power supply circuit, that is, the internal temperature value of the power supply control unit 20 is higher than the reference value, or the internal current value is larger than the reference value, or fed back. If the voltage value is greater than the reference value or the voltage generated by the tertiary winding is greater than the reference value, the power protection unit 27 switches the system from the normal mode to the latchup mode.

That is, in the latch-up mode, the power protection unit 27 interrupts the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 to stop the driving of the transformer 11. The power generator 10 controls the power voltages Vo, Vom, and Von not to be generated. Accordingly, power voltages Vo, Vom, and Von are not supplied to each part of the system until the power is turned on again by the user. Do not.

On the contrary, when the second level detection signal is input, the power protection unit 27 according to the restart mode suspends the operation of the power generation unit 10 by switching the system from the normal mode to the protection mode. When the detection signal of the first level is input, the system is switched from the protection mode to the restart mode to resume the operation of the power generator 10.

For example, when an abnormality occurs in a circuit on the primary side or the secondary side of the power supply circuit, that is, the internal temperature value of the power supply control unit 20 is higher than the reference value, or the internal current value is larger than the reference value, or fed back. The power protection unit 27 switches the system from the normal mode to the protection mode when the voltage value is larger than the reference value or the voltage generated by the tertiary winding is higher than the reference value.

That is, in the protection mode, the power protection unit 27 interrupts the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 to stop the driving of the transformer 11, thereby providing power. The generation unit 10 controls the power supply voltages Vo, Vom, and Von not to be generated. As a result, the power supply voltages Vo, Vom, and Von are not temporarily supplied to each system.

After switching to the protection mode in this way, when the detection signal of the first level is input to the power protection unit 27 again, the system is switched from the protection mode to the re-drive mode.

That is, in the restart mode, the power protection unit 27 supplies the PWM control signal generated from the PWM control signal generator 22 to the switching means 21 to drive the transformer 11 again. The power generator 10 controls the power voltages Vo, Vom, and Von to be regenerated, and accordingly, the power supply voltages Vo, Vom, and Von are supplied to each system.

However, in the power supply circuit according to the related art, when the power protection unit 27 according to the latchup mode is employed, the system is switched to the latchup mode even if a problem that can be recovered by itself occurs. There was a cumbersome problem of coming back.

In addition, when the power protection unit 27 according to the restart mode is adopted, an abnormal feedback voltage Vfb, power supply voltage Vcc, or overcurrent Id as shown in FIG. 20), there is a problem that a fire may occur because both the protection mode and the restart is performed repeatedly. In other words, when minute stress is continuously applied to a part or a circuit, a fire may occur even without a large energy, and thus there is a problem that a fire may occur when the protection mode and the driving mode are repeatedly repeated.

In addition, there is a problem that the start noise is repeatedly generated due to the repeated restart operation to make the user feel a risk.

In addition, there is a problem in that the light emitting diode is repeatedly operated due to the re-drive operation to reduce the life of the light emitting diode.

Accordingly, the present invention has been made to solve the above problems, to switch off the system to the latch-up mode to completely shut off the power supply in order to protect the system when the restart mode is repeatedly performed by the system abnormality. It is an object of the present invention to provide a power supply circuit of a video display device and a control method thereof.

The circuit according to the present invention for achieving the above object comprises: a power generator for receiving an AC power supply voltage from the outside in the normal mode to generate a predetermined DC power supply voltage and supply it to each system; If a problem occurs in the system, the system is switched from the normal mode to the protection mode to suspend the DC power voltage generation operation of the power generator. A power supply circuit of an image display device having a power control unit for resuming a DC power voltage generation operation of a generation unit, wherein the power control unit is configured to restart the system in a restart mode when the restart mode is repeatedly performed due to a system error. Switching to the latch-up mode may completely stop the DC power generation operation of the power generator.

In addition, the method of the present invention for achieving the above object, the process of determining whether the switch to the protected mode; Determining whether to switch back to the restart mode when the protection mode is switched; Counting the number of restarts when the system is switched to the restart mode; Determining whether the counted number of restarts coincides with a preset number of restarts; And when the counted number of restarts coincides with a preset number of restarts, switching the system from the restart mode to the latch-up mode to completely block power supply to the system.

In addition, another method of the present invention for achieving the above object is a process of determining whether the switch to the protected mode; Counting time T1 from the time when the protection mode is switched to the protection mode; Determining whether to switch back to the restart mode; Accumulating the counted time T1 at time T2 when the system is switched to the redrive mode; Determining whether the accumulated time T2 coincides with a preset time T3; And when the accumulated time T2 coincides with the preset time T3, switching the system from the re-drive mode to the latch-up mode to completely cut off the power supply of the system.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram illustrating a power supply circuit of an image display apparatus according to the present invention. Detailed description of the same parts as in the prior art will be omitted, and only the power control unit 20 will be described.

As shown in FIG. 3, the power control unit 20 receives an AC power supply voltage AC from an external source in a normal mode, and generates a predetermined DC power supply voltage Vo, Vo, and Vom and supplies the power to each system. (10) and; If a problem occurs in the system, the system is switched from the normal mode to the protection mode to suspend the DC power voltage (Vo, Vo, Vom) generation operation of the power generator 10, and when the problem is solved to protect the system In the power supply circuit of the image display device having a power control unit 20 for re-switching from the mode to the re-drive mode to resume the DC power voltage (Vo, Von, Vom) generation operation of the power generator 10, When the re-drive mode is repeatedly performed due to a system abnormality, the power control unit 20 switches the system from the re-drive mode to the latch-up mode so that the DC power voltages (Vo, Von, Vom) completely stops the generation operation.

The power control unit 20 counts the number of repetitions when the re-drive mode is repeatedly performed due to a system abnormality, and compares the counted number with a preset number of times, and if the counted number matches the preset number of times, the system. By switching from the re-drive mode to the latch-up mode to completely stop the DC power supply voltage (Vo, Von, Vom) generation operation of the power generator 10.

In addition, when the re-drive mode is repeatedly performed, the power control unit 20 counts the repeated time and compares the counted time with a preset time, and restarts the system when the counted time matches the preset time. By switching from the driving mode to the latch mode, the operation of generating the DC power voltages Vo, Vo, and Vom of the power generator 10 is completely stopped.

In addition, when the restart mode is repeatedly performed due to a system abnormality, the power control unit 20 switches the system from the restart mode to the latch-up mode and is supplied from the power generation unit 10 to the power control unit 10. Cut off DC power voltage completely.

Here, the power control unit 20 is switched on / off by a PWM control signal to drive the transformer 11 to determine the magnitudes of the DC power voltages Vo, Vo, and Vom generated by the power generation unit 20. Switching means 21 for adjusting; A PWM control signal generator 22 generating a PWM control signal by receiving a predetermined DC power voltage (Vo, Vo, Vom) output from the power generator 10 and outputting the PWM control signal to the switching means 21; Compare the current measurement value, the voltage measurement value, and the temperature measurement value with each reference value, and if the at least one measurement value is smaller than the reference value, output the detection signal of the first level, and if it is larger than the reference value, output the detection signal of the second level. Sensing units 24, 25 and 26; When the detection signal of the second level is input, the system is switched from the normal mode to the protection mode to cut off the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 so that the transformer 11 When the drive is paused and the detection signal of the second level is input, the system is switched from the protection mode to the re-drive mode to transmit the PWM control signal generated from the PWM control signal generator 22 to the switching means 21. A power protection unit 27 for re-supplying and driving the transistors 11 again; When the re-drive mode is repeatedly performed due to a system abnormality, the system is switched from the re-drive mode to the latch-up mode to block the PWM control signal supplied from the PWM control signal generator 22 to the switching means 11. A power cut-off unit 28 for completely stopping the driving of the transformer 11 is further included.

4 is an operational flowchart of a first embodiment for implementing the present invention.

As shown in FIG. 4, first, the power cutoff unit 28 protects the system from the normal mode by the detection signal output from the overcurrent detector 24, the overvoltage detector 25, or the temperature detector 26. It is determined whether the conversion to (S210).

The overcurrent detector 24, the overvoltage detector 25, and the temperature detector 25 each have a reference value for determining whether an input value is normal. In this case, when the values input to the above-described circuits are respectively equal to or less than the reference value, the sensing signal of the first level is output.

As a result of the determination in step S210, when the detection signal of the second level is output from the detection units 24, 25, and 26, the power cut-off unit 28 determines that the system is switched to the protection mode, and the detection unit It is determined whether the system is re-switched from the protection mode to the re-drive mode by the detection signal output from (24, 25, 26) (S220).

As a result of the determination in step S210, when the detection signal of the first level is output from the detection units 24, 25, and 26, the power cut-off unit 28 determines that the system has been switched to the restart mode, and restarts. The number of times is counted (S230).

In addition, the power cut-off unit 28 determines whether the number of restarts counted in the above-described process (S230) matches the preset number of restarts (S240).

As a result of the determination in the above-described process (S240), when the counted restart count is consistent with the preset restart count, the power cut-off unit 28 switches to the latch-up mode to cut off the power supplied to the system (S250). .

For example, the power cut-off unit 28 cuts off the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 or from the power generator 10 to the power controller 10. By stopping the driving of the transformer 11 by blocking the supplied DC power voltage, the power generation unit 10 controls the power voltages Vo, Vom, and Von not to be generated, and thus the power is again supplied by the user. The power supply voltages (Vo, Vom, and Von) are not supplied to each part of the system until they are turned on.

5 is an operational flowchart of a second embodiment for implementing the present invention.

As shown in FIG. 5, first, the power cutoff unit 28 is activated by a detection signal output from the overcurrent detector 24, the overvoltage detector 25, or the temperature detector 26. It is determined whether the conversion to (S310).

As a result of the determination in step S310, when the detection signal of the second level is output from the detection units 24, 25, and 26, the power cut-off unit 28 determines that the system is switched to the protection mode, and enters the protection mode. The time T1 is counted from the changed time point (S320).

Meanwhile, the power cutoff unit 28 determines whether the system is re-switched from the protection mode to the redrive mode by the detection signals output from the detection units 24, 25, and 26 (S330).

As a result of the determination in step S330, when the detection signal of the first level is output from the detectors 24, 25, and 26, the power cut-off unit 28 determines that the system has been switched to the restart mode, and counted. Time T1 is accumulated at time T2 and time T1 is initialized (S340).

The power cutoff unit 28 determines whether the time T2 accumulated in the above-described process S340 coincides with the preset time T3 (S350).

As a result of the determination in the above-described process (S350), when the accumulated time T2 coincides with the preset time T3, the power cut-off unit 28 switches to the latch-up mode to cut off the power supplied to the system (S360).

For example, the power cut-off unit 28 cuts off the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 or from the power generator 10 to the power controller 10. By stopping the driving of the transformer 11 by blocking the supplied DC power voltage, the power generation unit 10 controls the power voltages Vo, Vom, and Von not to be generated, and thus the power is again supplied by the user. The power supply voltages (Vo, Vom, and Von) are not supplied to each part of the system until they are turned on.

Meanwhile, in this case, in order to cut off power supplied to the system in the latch-up mode, the PWM control signal supplied from the PWM control signal generator 22 to the switching means 21 is cut off, or from the power generator 10. An embodiment of blocking a DC power voltage supplied to the power control unit 10 has been described, but may be changed according to a circuit configuration of a person skilled in the art.

In addition, although the embodiments of the present invention have been described in which the number of restarts is counted to cut off the power of the system, or the system is cut off by checking the cumulative time according to the restart, the above-described two implementations are performed according to the circuit configuration of those skilled in the art. Examples can be combined and performed in one way.

Therefore, as described above, in the present invention, when the restart mode is repeatedly performed due to a system abnormality, a fire that may occur when the restart mode is repeated by switching off the system to the latch up mode and completely shutting off the power supply to protect the system. The effect is that it can be prevented in advance.

Claims (8)

A power generation unit which receives an AC power supply voltage from an external source in a normal mode and generates a predetermined DC power supply voltage and supplies it to each system; If a problem occurs in the system, the system is switched from the normal mode to the protection mode to suspend the DC power voltage generation operation of the power generation unit.If the problem is solved, the system is switched from the protection mode to the restart mode again to restore the power. In the power supply circuit of the image display device having a power control unit for restarting the DC power voltage generation operation of the generation unit, The power control unit, When the restart mode is repeatedly performed due to a system abnormality, the power supply circuit of the image display apparatus is characterized in that the system is changed from the restart mode to the latch-up mode to completely stop the DC power voltage generation operation of the power generator. . The method of claim 1, wherein the power control unit, When the restart mode is repeatedly executed due to a system abnormality, the number of repetitions is counted, and the counted number of times is compared with a preset number of times. If the counted number matches the predetermined number of times, the system is latched up in the restart mode. The power supply circuit of the image display device, characterized in that to switch to the mode to completely stop the DC power supply voltage generation operation of the power generator. The method of claim 1, wherein the power control unit, When the restart mode is repeatedly performed, the repeated time is counted and the counted time is compared with the preset time. If the counted time coincides with the preset time, the system is switched from the restart mode to the latch mode. The power supply circuit of the image display device, characterized in that to completely stop the DC power voltage generation operation of the power generator. The method of claim 1, wherein the power control unit, When the restart mode is repeatedly performed due to a system abnormality, the system is switched from the restart mode to the latch-up mode to completely cut off the DC power voltage supplied from the power generator to the power controller. Power supply circuit. The method of claim 1, wherein the power generation unit, A power supply circuit of an image display apparatus, characterized by converting a voltage induced in a secondary winding of a transformer into a predetermined DC power supply voltage by an AC power supply voltage introduced into a primary winding of a transformer from outside. The method of claim 5, wherein the power control unit, Switching means for switching on / off by a PWM control signal to drive the transformer to adjust the magnitude of the DC power voltage generated by the power generator; A PWM control signal generator for generating a PWM control signal by receiving a feedback of a predetermined DC power voltage output from the power generator and outputting the PWM control signal to the switching means; Compare the current measurement value, the voltage measurement value, and the temperature measurement value with each reference value, and if at least one measurement value is smaller than the reference value, output a detection signal of the first level, and if larger than the reference value, output a detection signal of the second level. Sensor; When the detection signal of the second level is input, the system is switched from the normal mode to the protection mode to interrupt the PWM control signal supplied from the PWM control signal generator to the switching means to temporarily stop driving of the transformer. When a two-level detection signal is input, the power protection unit for switching the system from the protection mode to the re-drive mode to re-drive the transistor by supplying the PWM control signal generated from the PWM control signal generator to the switching means. ; When the restart mode is repeatedly performed due to a system abnormality, the system is switched from the restart mode to the latch-up mode to block the PWM control signal supplied from the PWM control signal generator to the switching means to completely drive the transformer. The power supply circuit of the video display device, characterized in that further comprises a power cut-off unit to stop. Determining whether to switch to the protection mode; Determining whether to switch back to the restart mode when the switch is to the protection mode; Counting the number of restarts when the system is switched to the restart mode; Determining whether the counted number of restarts coincides with a preset number of restarts; And If the count of restart times is equal to the preset number of restarts, the power supply circuit of the video display device is characterized in that the system is switched from the restart mode to the latch-up mode to completely cut off the power supply of the system. Control method. Determining whether to switch to the protection mode; Counting time T1 from the time when the protection mode is switched to the protection mode; Determining whether to switch back to the re-drive mode; Accumulating the counted time T1 at time T2 when the system is switched to the redrive mode; Determining whether the accumulated time T2 coincides with a preset time T3; And And when the accumulated time T2 coincides with the preset time T3, switching the system from the restart mode to the latch-up mode to completely cut off the power supply of the system.

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