JP3122962U7 - - Google Patents

Description

LCD television and backlight power supply circuit

The present invention relates to a backlight power supply circuit, and more particularly to a backlight power supply circuit that controls the voltage of a separately-excited inverter circuit and a liquid crystal television that uses the backlight power supply circuit.

The inverter type power supply circuit converts an AC commercial power source into a DC power source by a rectifier circuit, and converts the converted DC power source into a predetermined AC power source by a switch action such as a transistor. In addition, the inverter type power supply circuit has a large voltage and a small current, and therefore consumes little power. FIG. 5 is a diagram showing a power supply substrate for backlight. From the figure, the backlight power supply circuit generates a predetermined power supply voltage based on the rectifier circuit 1 that rectifies the AC power supply and the power supply rectified by the rectifier circuit 1 and supplies power to the backlight 4. And a separately excited inverter circuit 2.

The above-described backlight power supply circuit monitors the overvoltage flowing through the backlight 4 with the overvoltage detection circuit 5. When the overvoltage flows through the backlight 4, the controller 6 immediately starts the separately excited inverter circuit 2. It is a mechanism to give feedback to. However, if dust or the like accumulates on a line that supplies power to the backlight 4, a leak current may flow through the dust. When the leakage current increases, the power consumption increases, and the amount of heat generation increases, causing the circuit to burn and causing damage to the substrate.

However, when a leakage current flows through the substrate, the voltage of the power removal capacitor for supplying the output voltage to the backlight 4 decreases. For this reason, the above-described overvoltage detection circuit 5 cannot prevent the occurrence of leakage current.

As a method for detecting a decrease in the output voltage flowing through the backlight, a method is disclosed in which a tube current detection circuit is provided on the backlight power supply board to detect an increase in current accompanying a decrease in the output voltage (for example, a patent Reference 1). JP 05-226084 A

The device of Patent Document 1 described above has the following problems. That is, since the inverter type power supply circuit is characterized by a large voltage and a small current, when a decrease in the output voltage is detected using the current, a minute change in the current value is detected. For this reason, it is difficult to adjust a circuit for detecting the current.

The present invention has been made in view of the above problems, and a backlight power supply substrate capable of preventing leakage current generated in the substrate based on the value of the output voltage flowing in the backlight, and the backlight An object is to provide a liquid crystal television using a power supply circuit.

In order to solve the above-mentioned problem, in the device according to claim 1 of the present invention, the video signal and the audio signal are generated based on the television radio wave received by the tuner unit, and the control unit having a microcomputer performs the control. A rectifier circuit comprising a digital substrate, a liquid crystal display that transmits a light source from a backlight based on the video signal, displays a video, a speaker that outputs audio based on the audio signal, and an AC power supplied from an outlet In a liquid crystal television having an analog substrate for supplying the converted power to the digital substrate and the liquid crystal display, converting the voltage to a predetermined voltage based on the rectified power source
The analog board converts a voltage required for driving the backlight based on the rectified power source, and an output voltage converted by the separately excited inverter circuit through a transformer in a positive cycle. A backlight driving circuit for supplying an output voltage to the backlight by outputting the negative voltage to a negative voltage collector and a negative voltage negative voltage generator, respectively, and a positive voltage negative voltage collector And an overvoltage detection circuit for detecting an overvoltage applied to the backlight,
The negative cycle voltage is connected in parallel with the voltage-dissipating capacitor, and the voltage of the negative-current capacitor that discharges the negative cycle voltage is used as a detection voltage. The detection voltage is composed of a diode and a smoothing capacitor. After smoothing by a smoothing circuit, a drop in the detected voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV via an operational amplifier, and the output voltage is higher than the threshold voltage. Is smaller, the microcomputer has a leakage current detection circuit that outputs a leakage current detection signal from the operational amplifier, and the microcomputer drives the backlight drive to the separately excited inverter circuit when the overvoltage detection circuit detects an overvoltage. Feedback control is performed so that the output voltage output to the circuit becomes the specified voltage, and the leakage current detection signal is output from the leakage current detection circuit. If the has a configuration for controlling to stop the voltage supply to the backlight drive circuit from the separately-excited inverter circuit.

The invention according to claim 1 configured as described above relates to a liquid crystal television in which a backlight power supply circuit for supplying power to a backlight is arranged on an analog substrate. The backlight power supply circuit generates an output voltage of the backlight by a separately-excited separately-excited inverter circuit. At this time, the backlight power supply circuit includes a leakage current detection circuit that compares the output voltage of the backlight with a threshold voltage using an operational amplifier. The leakage current detection circuit described above is a circuit that detects the occurrence of leakage current based on a decrease in output voltage. If the operational amplifier determines that the detection voltage is lower than the comparison voltage, the leakage current output from the operational amplifier The control unit stops supplying the output voltage of the separately excited inverter circuit to the backlight by the detection signal. The control unit also performs backlight overvoltage detection at the same time, and simplifies the circuit by using the feedback control unit in two circuits.

In order to achieve the above object, in the backlight power supply circuit according to claim 2, in the backlight power supply circuit for supplying a predetermined power to the backlight using a separately excited inverter type power supply circuit. ,
The output voltage converted by the separately-excited inverter circuit is output to a discharge capacitor that discharges a positive cycle voltage and a negative discharge capacitor that discharges a negative cycle voltage via a transformer, respectively. A backlight drive circuit to be supplied, an overvoltage detection circuit for detecting an overvoltage applied to the backlight, connected in parallel with a voltage removal capacitor for discharging the positive cycle voltage, and a negative cycle voltage. Connected in parallel with the voltage-dissipating capacitor, and after the voltage of the negative-current capacitor that discharges the negative cycle voltage is detected voltage, the detected voltage is smoothed by a smoothing circuit composed of a diode and a smoothing capacitor. In addition, a drop in the detection voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV through an operational amplifier. A leakage current detection circuit for outputting a leakage current detection signal from the operational amplifier when the output voltage is smaller than the threshold voltage, and the overexcited inverter when the overvoltage detection circuit detects an overvoltage. When feedback control is performed so that the output voltage output to the backlight is set to a specified voltage in the circuit, and the leakage current detection signal is output from the leakage current detection circuit, the voltage to the backlight from the separately excited inverter circuit The supply is stopped .

In the device according to claim 2 configured as described above, when the voltage drop detecting means detects a drop in the output voltage output to the backlight, the leakage current preventing means is connected to the backlight from the separately excited inverter circuit. Stop the voltage supply.

Further, in the backlight power supply circuit according to claim 2, the voltage drop detecting means may detect a drop in the output voltage by comparing the output voltage with a threshold voltage using an operational amplifier. Good.

In the device configured as described above, the voltage drop detection means detects a drop in the output voltage of the backlight by comparing the output voltage and the threshold voltage using an operational amplifier.

Further, the backlight power supply circuit includes an overvoltage detection circuit for detecting an overvoltage, and a feedback control unit for controlling the separately-excited inverter circuit based on the signal voltage from the overvoltage detection circuit, The leakage current preventing means may be configured to stop outputting the voltage of the separately excited inverter circuit by outputting a leakage current detection signal to the feedback control unit.

In the device configured as described above, the leakage current prevention unit diverts the feedback control unit of the overvoltage detection unit and outputs the leakage current detection signal to the feedback control unit to stop the voltage of the separately excited inverter circuit. To stop.

As described above, according to the present invention, since a leakage current is prevented based on the output voltage of the backlight, it is possible to configure a detection means having a simple structure that is compatible with a circuit with low current consumption.
Further, since an operational amplifier is used as the detection means, an inexpensive detection means combining commercially available circuit elements can be configured.
Since a part of the feedback control circuit for overvoltage detection is used, the detection means can be configured with a simple structure.
Furthermore, it is needless to say that in a more specific configuration as in claim 1, the same effects as those of the above-described inventions in claim 2 can be obtained.

As a specific description of the backlight power supply circuit of the present invention, a description will be given based on a liquid crystal television using the backlight power supply circuit. Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of LCD television
(2) Configuration of power supply circuit for backlight
(3) Summary

(1) Configuration of Liquid Crystal Television A first embodiment embodying a liquid crystal television according to the present invention will be described below with reference to FIGS. FIG. 1 is a block diagram of a liquid crystal television 10 of the present invention. As shown in the figure, the liquid crystal television 10 includes a digital board 11, an analog board 14, a liquid crystal display 13, a speaker 15, a housing 16 for housing the above components, and a remote controller 18. The function of each part will be described below.

The digital board 11 includes a tuner unit 11a, a video signal processing unit 11b, an audio signal processing unit 11c, and a control unit 12. As shown in FIG. 1, each component in the digital board 11 is connected to the control unit 12 through a bus 11 d and performs each function under the control of the control unit 12. The control unit 12 includes a microcomputer 12a as a control center, a recording unit 12b such as a ROM and a RAM, a remote control I / F 12c that receives an operation signal from the remote control 18, and an OSD unit 12d for generating an OSD video. It is a configuration. When an infrared signal is transmitted to the remote control I / F 12c by operating the operation key of the remote controller 18, the remote control I / F 12c converts the received infrared signal into an operation signal having a predetermined voltage and outputs it to the microcomputer 12a. The microcomputer 12a receives the operation signal from the remote control I / F 12c and outputs a control signal to each element on the digital board 11 through the bus 11d based on the control program recorded in the recording unit 12b.

When the tuner unit 11a accepts the operation signal from the control unit 12, the tuner unit 11a selects only a specific frequency band of the television radio wave received by the antenna 11a1, and the video signal is based on the television radio wave of the selected specific frequency band. And chroma control to generate audio signals. The generated video signal is sent to the video signal processing unit 11b, and the audio signal is sent to the audio signal processing unit 11c. The tuner unit 11a of the present invention may be one that receives analog broadcasts, one that receives both analog broadcasts and digital broadcasts, or one that receives only digital broadcasts.

The video signal processing unit 11b receives the generated video signal, generates an RGB signal corresponding to each gradation of RGB for constituting the screen, and performs predetermined signal processing on the generated RGB signal. Further, the RGB signals are decomposed and output to the liquid crystal panel 13b so as to correspond to the number of pixels of the liquid crystal panel 13b described later.

The audio signal processing unit 11c receives the generated audio signal and performs signal processing such as amplification on the audio signal based on the control signal from the control unit 12. The sound signal subjected to the signal processing is then output to the speaker 15 and output as sound.

The liquid crystal display 13 includes a liquid crystal panel 13b in which pixels filled with a liquid crystal substance are arranged in a matrix, a drive circuit 13a that applies a drive voltage to the liquid crystal panel 13b, and a backlight 13c that illuminates light from the back of the liquid crystal panel 13b. It is the structure which has. The drive circuit 13a applies a drive voltage, which is an applied voltage for each row, to a predetermined pixel of the liquid crystal panel 13b based on the RGB signal divided corresponding to each pixel of the liquid crystal panel 13b by the video signal processing unit 11b. I will do it. In the liquid crystal panel 13b, pixels filled with a liquid crystal substance whose molecular arrangement is changed by a driving voltage are arranged in a matrix. The above-described pixels have a set of pixels corresponding to each color of RGB, and each gradation of RGB is changed by changing the transmittance of light from the backlight of a specific pixel by the applied voltage from the drive circuit 13a. Change to display a color screen. As described above, the backlight 13c is used as a light source of light that is transmitted from the pixel by applying light from behind the liquid crystal panel 13b. Examples of the fluorescent tube used by the backlight 13c include those between cold cathodes, and the shape may be a U-shaped tube, a straight tube, or a pseudo U-shaped tube.

The analog substrate 14 is mounted with a power supply circuit that supplies power necessary for the digital substrate 11 and the liquid crystal display 13 described above. FIG. 2 is a block diagram of the analog board. As shown in the figure, the analog substrate 14 includes a rectifier circuit 14a, a main transformer 14b, and power supply circuits 14c, 14d, and 14e. The commercial 100V AC power supplied from the outlet 17 is full-wave rectified by the rectifier circuit 14a and converted into a DC power, and then applied to the primary coil 14b1 of the main transformer 14b. The rectifier circuit 14a of the present invention may be a bridge circuit using a diode. On the opposite side of the primary side coil 14b1 of the main transformer 14b, a secondary side coil 14b2 having a different winding ratio is arranged, and an electromotive force is generated in the secondary side coil 14b2 by mutual induction. The secondary electromotive force 14b2 outputs the electromotive force to the power supply circuits 14c, 14d and 14e, which are DC / DC converters. The power supply circuits 14c, 14d, and 14e supply the necessary power supply voltage to the digital substrate 11 and the liquid crystal display 13 by boosting or reducing the electromotive force divided by the chopper circuit or the dropper circuit.

(2) Configuration of Backlight Power Supply Circuit FIG. 3 is a configuration diagram of a backlight power supply circuit that is a power supply circuit for supplying power to the backlight 13c. As shown in the figure, the backlight power supply circuit 19 includes a separately-excited inverter circuit 20, a backlight drive circuit 22, an overvoltage detection circuit 24, and a leak current detection circuit (voltage drop detection means) 23. . The separately excited inverter circuit 20 receives the DC voltage output from the rectifier circuit 14a by the divided voltage from the secondary coil 14b2, and generates an AC voltage having a predetermined voltage value by using the switching operation of the transistor. The separately excited inverter circuit 20 as an embodiment of the present invention uses a separately excited inverter circuit.

The AC voltage generated by the separately excited inverter circuit 20 is applied to the primary side coil 21 a of the transformer 21. Secondary side coils 21b and 21c are arranged on the opposite side of the primary side coil 21a of the transformer 21, and an electromotive force is applied to the secondary side coils 21b and 21c by mutual dielectrics. At this time, the positive frequency side of the AC voltage is applied to the secondary coil 21b and is also discharged to the discharge capacitors 22a and 22b to generate an output voltage with a positive period. Further, the negative cycle AC voltage is applied to the secondary coil 21c, and is also applied to the power strip capacitors 22c and 22d to generate a negative cycle output voltage.

Further, the backlight power supply circuit 19 has an overvoltage detection circuit 24 in order to prevent an overvoltage from being applied to the backlight 13c. The overvoltage detection circuit 24 detects a divided voltage between the discharging capacitors 22c and 22d, and outputs an overvoltage detection signal to the microcomputer 12a based on the detected voltage value. When the microcomputer 12a accepts the overvoltage detection signal, feedback is realized by giving an instruction to reduce the voltage applied to the transformer 21 by the separately excited inverter circuit 20 to a specified voltage. As the microcomputer 12a according to an embodiment of the present invention, a microcomputer is used to control the separately excited inverter circuit 20, but an IC chip on which a predetermined logic circuit is mounted may be used. Further, feedback may be executed using the microcomputer 12a mounted on the digital board 11.

Further, the backlight power supply circuit 19 has a leak current detection circuit 23 that detects the occurrence of a leak current. The leak current detection circuit 23 utilizes a phenomenon in which the output voltage of the power transfer capacitors 22a and 22b is reduced below the specified voltage when a leak current that is a leak current occurs. The leak current detection circuit 23 includes an operational amplifier 23a, a threshold power supply 23d, and a smoothing circuit composed of a diode 23b and a smoothing capacitor 23c. The function and overall operation of each element will be described below. The negative side of the operational amplifier 23a is connected between the discharge capacitors 22a and 22b of the backlight drive circuit 22 via a diode 23b and a smoothing capacitor 23c, and the divided voltage value between the discharge capacitors 22a and 22b is connected to the threshold power supply 23d. Compare with threshold voltage. The diode 23b and the smoothing capacitor 23c smooth out the divided voltage between the discharge capacitors 22a and 22b and adjust it to a constant voltage. The threshold voltage of the threshold power source 23d according to an embodiment of the present invention is DC 700 mV to 800 mV. The voltage value of the threshold power supply 23d is not limited to the above value, and is preferably determined in accordance with the characteristics of the power supply circuit.

The output side of the operational amplifier 23a is connected to the microcomputer 12a, and the generation of the AC voltage of the separately excited inverter circuit 20 is stopped based on the leak voltage detection signal output from the operational amplifier 23a. In the embodiment of the present invention, since the separately excited inverter circuit 20 realizes inverter control by the IC circuit, the microcomputer 12a outputs the voltage of the separately excited inverter circuit 20 by stopping the output of the start signal of the IC circuit. Stop. The method of stopping the voltage output of the separately excited inverter circuit 20 is not limited to the above method, and a separately excited inverter circuit stop signal from the microcomputer 12a may be connected to the base of the transistor.

Hereinafter, the voltage flow of the backlight power supply circuit will be illustrated with reference to FIG. When the output voltage is started to be supplied to the backlight 13c via the discharging capacitors 22a, 22b, 22c, and 22d, the half-wave rectification of the positive cycle of the output voltage that is discharged to the discharging capacitors 22a and 22b is divided as a detection voltage. And is smoothed by the diode 23b and the smoothing capacitor 23c and input to the negative side of the operational amplifier 23a. The upper graph in FIG. 4 shows the voltage value input to the negative side of the operational amplifier 23a with respect to time T. Moreover, the voltage value represented by the dotted line in the figure indicates 700 mV. From the figure, between T0 and T1, the detection voltage input to the negative side of the operational amplifier 23a is 700 mV or more. Therefore, the operational amplifier 23a does not output a leakage current detection signal, and the separately excited inverter circuit 20 is a driving voltage. Is output to the transformer 21.

Next, when the value of the detection voltage input to the operational amplifier 23a exceeds 700 mV after the time T1, the operational amplifier 23a outputs a leakage current output signal to the microcomputer 12a. The middle part of FIG. 4 is a diagram showing a leakage current detection signal output by the operational amplifier with respect to time T. When the divided value of the detection voltage falls below 700 mV at time T1, the operational amplifier 23a outputs a leak current detection signal having a predetermined voltage. The voltage value of the leakage current detection signal described above may be determined based on the reception voltage of the microcomputer 12a.

When the microcomputer 12a receives the leak current detection signal, the microcomputer 12a stops the start signal of the IC circuit of the separately excited inverter circuit 20 and stops the current flowing through the transformer 21. The lower part of FIG. 4 is a diagram illustrating the output of the separately excited inverter circuit stop signal output from the feedback control unit with respect to time T. From the figure, when the leak current detection signal output from the operational amplifier 23a exceeds a predetermined value at time T2, the microcomputer 12a outputs a separately excited inverter circuit stop signal for stopping the voltage output of the separately excited inverter circuit 20. To do. As a result, no current flows through the backlight 13c, and it is possible to prevent the substrate from being damaged in advance due to scorching near the backlight 13c due to leakage current.

(3) Summary In the backlight power supply circuit 19 of the present invention, the voltage drop detecting means 23 detects the drop in the output voltage by comparing the output voltage of the backlight with the threshold value 23d, and the leakage current preventing means. 12a stops the voltage supply from the separately excited inverter circuit 20 to the backlight 13c when the voltage drop detecting means 23 detects a drop in the output voltage. Therefore, based on the output voltage of the backlight 13c, the substrate is prevented from being damaged due to the generation of the leakage current, so that the leakage current preventing function can be configured with a simple structure. In addition, the circuit for detecting the leakage current is configured by a commercially available operational amplifier 23a, and the microcomputer 12a for the overvoltage detection circuit is used, so that the circuit can be simplified and easily configured.
Simplify the circuit by using it together with the circuit.

In order to achieve the above object, in the backlight power supply circuit according to claim 2, in the backlight power supply circuit for supplying a predetermined power to the backlight using a separately excited inverter type power supply circuit. ,
The output voltage converted by the separately-excited inverter circuit is output to the backlight using a transformer, and the output voltage is supplied to the backlight. A backlight driving circuit, an overvoltage detection circuit for detecting an overvoltage applied to the backlight, connected in parallel with a negative voltage collector for discharging the negative half-wave, and a negative voltage collector for discharging the positive half-wave; Connected in parallel, the divided voltage of the collector capacitor that discharges the positive half-wave is used as a detection voltage, and the detection voltage is smoothed by a smoothing circuit composed of a diode and a smoothing capacitor. A drop in the detection voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV, and the output voltage is higher than the threshold voltage. If the overvoltage detection circuit detects an overvoltage, the output voltage output to the back-excited inverter circuit to the backlight when the overvoltage detection circuit detects an overvoltage. The feedback control is performed so that the voltage becomes a specified voltage, and when the leak current detection signal is output from the leak current detection circuit, the voltage supply from the separately excited inverter circuit to the backlight is stopped.

In the device according to claim 2 configured as described above, when the voltage drop detecting means detects a drop in the output voltage output to the backlight, the leakage current preventing means is connected to the backlight from the separately excited inverter circuit. Since the voltage supply is stopped, the detection means having a simple structure with low current consumption can be configured.

Further, in the backlight power supply circuit according to claim 2, the voltage drop detecting means may detect a drop in the output voltage by comparing the output voltage with a threshold voltage using an operational amplifier. Good.
In the device configured as described above, the voltage drop detection means detects a drop in the output voltage of the backlight by comparing the output voltage and the threshold voltage using an operational amplifier, so a combination of commercially available circuit elements is combined. In addition, an inexpensive detection means can be configured.

3. The backlight power supply circuit according to claim 2, wherein the backlight power supply circuit includes an overvoltage detection circuit for detecting an overvoltage, and a separately excited inverter based on a signal voltage from the overvoltage detection circuit. A feedback control unit for controlling the circuit, and the leakage current prevention means may stop the output of the voltage of the separately excited inverter circuit by outputting a leakage current detection signal to the feedback control unit. .

In the device configured as described above, the leakage current prevention unit diverts the feedback control unit of the overvoltage detection unit and outputs the leakage current detection signal to the feedback control unit to stop the voltage of the separately excited inverter circuit. Therefore, a part of the feedback control circuit for detecting overvoltage is used, so that the detection means can be configured with a simple structure.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combination to apply. It is disclosed as.

It is a block block diagram of a liquid crystal television. It is a block block diagram of an analog board | substrate. It is a block diagram of the power supply circuit for backlights. It is a figure showing each signal. It is a figure of the conventional power supply circuit for backlights.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Liquid crystal television, 11 ... Digital board, 11a ... Tuner part, 11b ... Video signal processing part, 11c ... Audio | voice signal processing part, 11d ... Bus, 11a1 ... Antenna, 12 ... Control part, 12a ... Microcomputer, 12b ... Recording , 12c: Remote control I / F, 12d: OSD unit, 13 ... Liquid crystal display, 13a ... Drive circuit, 13b ... Liquid crystal panel, 13c ... Backlight, 14 ... Analog substrate, 14a ... Rectifier circuit, 14b ... Main transformer, 14c DESCRIPTION OF SYMBOLS ... Power supply circuit, 14d ... Power supply circuit, 14e ... Power supply circuit, 14b1 ... Primary side coil, 14b2 ... Secondary side coil, 15 ... Speaker, 16 ... Housing, 17 ... Outlet, 18 ... Remote control, 19 ... Backlight Power supply circuit, 20 ... separately excited inverter circuit, 21 ... transformer, 21a ... primary side coil, 21b ... secondary side coil, 21c ... secondary side 22 ... Backlight drive circuit, 22a ... Deletion capacitor, 22b ... Deletion capacitor, 22c ... Deletion capacitor, 22d ... Deletion capacitor, 23 ... Leakage current detection circuit, 23a ... Operational amplifier, 23b ... Diode, 23c ... Smoothing capacitor, 23d ... Power supply for threshold, 24 ... Overvoltage detection circuit

LCD television and backlight power supply circuit

The present invention relates to a backlight power supply circuit, and more particularly to a backlight power supply circuit that controls the voltage of a separately-excited inverter circuit and a liquid crystal television that uses the backlight power supply circuit.

The inverter type power supply circuit converts an AC commercial power source into a DC power source by a rectifier circuit, and converts the converted DC power source into a predetermined AC power source by a switch action such as a transistor. In addition, the inverter type power supply circuit has a large voltage and a small current, and therefore consumes little power. FIG. 5 is a diagram showing a power supply substrate for backlight. From the figure, the backlight power supply circuit generates a predetermined power supply voltage based on the rectifier circuit 1 that rectifies the AC power supply and the power supply rectified by the rectifier circuit 1 and supplies power to the backlight 4. And a separately excited inverter circuit 2.

The above-described backlight power supply circuit monitors the overvoltage flowing through the backlight 4 with the overvoltage detection circuit 5. When the overvoltage flows through the backlight 4, the controller 6 immediately starts the separately excited inverter circuit 2. It is a mechanism to give feedback to. However, if dust or the like accumulates on a line that supplies power to the backlight 4, a leak current may flow through the dust. When the leakage current increases, the power consumption increases, and the amount of heat generation increases, causing the circuit to burn and causing damage to the substrate.

However, when a leakage current flows through the substrate, the voltage of the power removal capacitor for supplying the output voltage to the backlight 4 decreases. For this reason, the above-described overvoltage detection circuit 5 cannot prevent the occurrence of leakage current.

As a method for detecting a decrease in the output voltage flowing through the backlight, a method is disclosed in which a tube current detection circuit is provided on the backlight power supply board to detect an increase in current due to the decrease in the output voltage (for example, a patent). Reference 1). JP 05-226084 A

The device of Patent Document 1 described above has the following problems. That is, since the inverter type power supply circuit is characterized by a large voltage and a small current, when a decrease in the output voltage is detected using the current, a minute change in the current value is detected. For this reason, it is difficult to adjust a circuit for detecting the current.

The present invention has been made in view of the above problems, and a backlight power supply substrate capable of preventing leakage current generated in the substrate based on the value of the output voltage flowing in the backlight, and the backlight An object is to provide a liquid crystal television using a power supply circuit.

In order to solve the above-mentioned problem, in the device according to claim 1 of the present invention, the video signal and the audio signal are generated based on the television radio wave received by the tuner unit, and the control unit having a microcomputer performs the control. A rectifier circuit comprising a digital substrate, a liquid crystal display that transmits a light source from a backlight based on the video signal, displays a video, a speaker that outputs audio based on the audio signal, and an AC power supplied from an outlet In a liquid crystal television having an analog substrate for supplying the converted power to the digital substrate and the liquid crystal display, converting the voltage to a predetermined voltage based on the rectified power source
The analog board converts a voltage required for driving the backlight based on the rectified power source, and an output voltage converted by the separately excited inverter circuit through a transformer in a positive cycle. A backlight driving circuit for supplying an output voltage to the backlight by outputting the negative voltage to a negative voltage collector and a negative voltage negative voltage generator, respectively, and a positive voltage negative voltage collector And an overvoltage detection circuit for detecting an overvoltage applied to the backlight,
The negative cycle voltage is connected in parallel with the voltage-dissipating capacitor, and the voltage of the negative-current capacitor that discharges the negative cycle voltage is used as a detection voltage. The detection voltage is composed of a diode and a smoothing capacitor. After smoothing by a smoothing circuit, a drop in the detected voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV via an operational amplifier , and the output voltage is higher than the threshold voltage. Is smaller, the microcomputer has a leakage current detection circuit that outputs a leakage current detection signal from the operational amplifier, and the microcomputer drives the backlight drive to the separately excited inverter circuit when the overvoltage detection circuit detects an overvoltage. performs feedback control so that the output voltage to be output to the circuit to a specified voltage, the leakage current detection signal from the leakage current detection circuit of the output If the has a configuration for controlling to stop the voltage supply to the backlight drive circuit from the separately-excited inverter circuit.

The invention according to claim 1 configured as described above relates to a liquid crystal television in which a backlight power supply circuit for supplying power to a backlight is arranged on an analog substrate. The backlight power supply circuit generates an output voltage of the backlight by a separately-excited separately-excited inverter circuit. At this time, the backlight power supply circuit includes a leakage current detection circuit that compares the output voltage of the backlight with a threshold voltage using an operational amplifier. The leakage current detection circuit described above is a circuit that detects the occurrence of leakage current based on a decrease in output voltage. If the operational amplifier determines that the detection voltage is lower than the comparison voltage, the leakage current output from the operational amplifier The control unit stops supplying the output voltage of the separately excited inverter circuit to the backlight by the detection signal. The control unit also performs backlight overvoltage detection at the same time, and simplifies the circuit by using the feedback control unit in two circuits.

In order to achieve the above object, in the backlight power supply circuit according to claim 2, in the backlight power supply circuit for supplying a predetermined power to the backlight using a separately excited inverter type power supply circuit. ,
The output voltage converted by the separately-excited inverter circuit is output to a discharge capacitor that discharges a positive cycle voltage and a negative discharge capacitor that discharges a negative cycle voltage via a transformer, respectively. A backlight drive circuit to be supplied, an overvoltage detection circuit for detecting an overvoltage applied to the backlight, connected in parallel with a voltage removal capacitor for discharging the positive cycle voltage, and a negative cycle voltage. Connected in parallel with the voltage-dissipating capacitor, and after the voltage of the negative-current capacitor that discharges the negative cycle voltage is detected voltage, the detected voltage is smoothed by a smoothing circuit composed of a diode and a smoothing capacitor. In addition, a drop in the detection voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV through an operational amplifier. If the output voltage is less than the threshold voltage, when and a leakage current detection circuit for outputting a leak current detection signal from the operational amplifier, the overvoltage detection circuit detects the overvoltage, the separately excited inverter When feedback control is performed so that the output voltage output to the backlight is set to a specified voltage in the circuit, and the leakage current detection signal is output from the leakage current detection circuit, the voltage to the backlight from the separately excited inverter circuit The supply is stopped .

In the device according to claim 2 configured as described above, when the voltage drop detecting means detects a drop in the output voltage output to the backlight, the leakage current preventing means is connected to the backlight from the separately excited inverter circuit. Stop the voltage supply.

Further, in the backlight power supply circuit according to claim 2, the voltage drop detecting means may detect a drop in the output voltage by comparing the output voltage with a threshold voltage using an operational amplifier. Good.

In the device configured as described above, the voltage drop detection means detects a drop in the output voltage of the backlight by comparing the output voltage and the threshold voltage using an operational amplifier.

Further, the backlight power supply circuit includes an overvoltage detection circuit for detecting an overvoltage, and a feedback control unit for controlling the separately-excited inverter circuit based on the signal voltage from the overvoltage detection circuit, The leakage current preventing means may be configured to stop outputting the voltage of the separately excited inverter circuit by outputting a leakage current detection signal to the feedback control unit.

In devised constructed as described above, the leakage current preventing means is configured to divert the feedback control unit of the overvoltage detection means, stopped voltage of the separately excited inverter circuit by outputting a leak current detection signal to the feedback control unit To stop.

As described above, according to the present invention, since a leakage current is prevented based on the output voltage of the backlight, it is possible to configure a detection means having a simple structure that is compatible with a circuit with low current consumption.
Also, Since an operational amplifier is used as the detection means, an inexpensive detection means combining commercially available circuit elements can be configured.
And Since a part of the feedback control circuit for detecting overvoltage is used, the detection means can be configured with a simple structure.
Furthermore, it goes without saying that in a more specific configuration as in claim 1 , the same effect as in the invention of claim 2 described above can be achieved.

As a specific description of the backlight power supply circuit of the present invention, a description will be given based on a liquid crystal television using the backlight power supply circuit. Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of LCD television
(2) Configuration of power supply circuit for backlight
(3) Summary

(1) Configuration of Liquid Crystal Television A first embodiment embodying a liquid crystal television according to the present invention will be described below with reference to FIGS. FIG. 1 is a block diagram of a liquid crystal television 10 of the present invention. As shown in the figure, the liquid crystal television 10 includes a digital board 11, an analog board 14, a liquid crystal display 13, a speaker 15, a housing 16 for housing the above components, and a remote controller 18. The function of each part will be described below.

The digital board 11 includes a tuner unit 11a, a video signal processing unit 11b, an audio signal processing unit 11c, and a control unit 12. As shown in FIG. 1, each component in the digital board 11 is connected to the control unit 12 through a bus 11 d and performs each function under the control of the control unit 12. The control unit 12 includes a microcomputer 12a as a control center, a recording unit 12b such as a ROM and a RAM, a remote control I / F 12c that receives an operation signal from the remote control 18, and an OSD unit 12d for generating an OSD video. It is a configuration. When an infrared signal is transmitted to the remote control I / F 12c by operating the operation key of the remote controller 18, the remote control I / F 12c converts the received infrared signal into an operation signal having a predetermined voltage and outputs it to the microcomputer 12a. The microcomputer 12a receives the operation signal from the remote control I / F 12c and outputs a control signal to each element on the digital board 11 through the bus 11d based on the control program recorded in the recording unit 12b.

When the tuner unit 11a accepts the operation signal from the control unit 12, the tuner unit 11a selects only a specific frequency band of the television radio wave received by the antenna 11a1, and the video signal is based on the television radio wave of the selected specific frequency band. And chroma control to generate audio signals. The generated video signal is sent to the video signal processing unit 11b, and the audio signal is sent to the audio signal processing unit 11c. The tuner unit 11a of the present invention may be one that receives analog broadcasts, one that receives both analog broadcasts and digital broadcasts, or one that receives only digital broadcasts.

The video signal processing unit 11b receives the generated video signal, generates an RGB signal corresponding to each gradation of RGB for constituting the screen, and performs predetermined signal processing on the generated RGB signal. Further, the RGB signals are decomposed and output to the liquid crystal panel 13b so as to correspond to the number of pixels of the liquid crystal panel 13b described later.

The audio signal processing unit 11c receives the generated audio signal and performs signal processing such as amplification on the audio signal based on the control signal from the control unit 12. The sound signal subjected to the signal processing is then output to the speaker 15 and output as sound.

The liquid crystal display 13 includes a liquid crystal panel 13b in which pixels filled with a liquid crystal substance are arranged in a matrix, a drive circuit 13a that applies a drive voltage to the liquid crystal panel 13b, and a backlight 13c that illuminates light from the back of the liquid crystal panel 13b. It is the structure which has. The drive circuit 13a applies a drive voltage, which is an applied voltage for each row, to a predetermined pixel of the liquid crystal panel 13b based on the RGB signal divided corresponding to each pixel of the liquid crystal panel 13b by the video signal processing unit 11b. I will do it. In the liquid crystal panel 13b, pixels filled with a liquid crystal substance whose molecular arrangement is changed by a driving voltage are arranged in a matrix. The above-described pixels have a set of pixels corresponding to each color of RGB, and each gradation of RGB is changed by changing the transmittance of light from the backlight of a specific pixel by the applied voltage from the drive circuit 13a. Change to display a color screen. As described above, the backlight 13c is used as a light source of light that is transmitted from the pixel by applying light from behind the liquid crystal panel 13b. Examples of the fluorescent tube used by the backlight 13c include those between cold cathodes, and the shape may be a U-shaped tube, a straight tube, or a pseudo U-shaped tube.

The analog substrate 14 is mounted with a power supply circuit that supplies power necessary for the digital substrate 11 and the liquid crystal display 13 described above. FIG. 2 is a block diagram of the analog board. As shown in the figure, the analog substrate 14 includes a rectifier circuit 14a, a main transformer 14b, and power supply circuits 14c, 14d, and 14e. The commercial 100V AC power supplied from the outlet 17 is full-wave rectified by the rectifier circuit 14a and converted into a DC power, and then applied to the primary coil 14b1 of the main transformer 14b. The rectifier circuit 14a of the present invention may be a bridge circuit using a diode. On the opposite side of the primary side coil 14b1 of the main transformer 14b, a secondary side coil 14b2 having a different winding ratio is arranged, and an electromotive force is generated in the secondary side coil 14b2 by mutual induction. The secondary electromotive force 14b2 outputs the electromotive force to the power supply circuits 14c, 14d and 14e, which are DC / DC converters. The power supply circuits 14c, 14d, and 14e supply the necessary power supply voltage to the digital substrate 11 and the liquid crystal display 13 by boosting or reducing the electromotive force divided by the chopper circuit or the dropper circuit.

(2) Configuration of Backlight Power Supply Circuit FIG. 3 is a configuration diagram of a backlight power supply circuit that is a power supply circuit for supplying power to the backlight 13c. As shown in the figure, the backlight power supply circuit 19 includes a separately-excited inverter circuit 20, a backlight drive circuit 22, an overvoltage detection circuit 24, and a leak current detection circuit (voltage drop detection means) 23. . The separately excited inverter circuit 20 receives the DC voltage output from the rectifier circuit 14a by the divided voltage from the secondary coil 14b2, and generates an AC voltage having a predetermined voltage value by using the switching operation of the transistor. The separately excited inverter circuit 20 as an embodiment of the present invention uses a separately excited inverter circuit.

The AC voltage generated by the separately excited inverter circuit 20 is applied to the primary side coil 21 a of the transformer 21. Secondary side coils 21b and 21c are arranged on the opposite side of the primary side coil 21a of the transformer 21, and an electromotive force is applied to the secondary side coils 21b and 21c by mutual dielectrics. At this time, the positive frequency side of the AC voltage is applied to the secondary coil 21b and is also discharged to the discharge capacitors 22a and 22b to generate an output voltage with a positive period. Further, the negative cycle AC voltage is applied to the secondary coil 21c, and is also applied to the power strip capacitors 22c and 22d to generate a negative cycle output voltage.

Further, the backlight power supply circuit 19 has an overvoltage detection circuit 24 in order to prevent an overvoltage from being applied to the backlight 13c. The overvoltage detection circuit 24 detects a divided voltage between the discharging capacitors 22c and 22d, and outputs an overvoltage detection signal to the microcomputer 12a based on the detected voltage value. When the microcomputer 12a accepts the overvoltage detection signal, feedback is realized by giving an instruction to reduce the voltage applied to the transformer 21 by the separately excited inverter circuit 20 to a specified voltage. As the microcomputer 12a according to an embodiment of the present invention, a microcomputer is used to control the separately excited inverter circuit 20, but an IC chip on which a predetermined logic circuit is mounted may be used. Further, feedback may be executed using the microcomputer 12a mounted on the digital board 11.

Further, the backlight power supply circuit 19 has a leak current detection circuit 23 that detects the occurrence of a leak current. The leak current detection circuit 23 utilizes a phenomenon in which the output voltage of the power transfer capacitors 22a and 22b is reduced below the specified voltage when a leak current that is a leak current occurs. The leak current detection circuit 23 includes an operational amplifier 23a, a threshold power supply 23d, and a smoothing circuit composed of a diode 23b and a smoothing capacitor 23c. The function and overall operation of each element will be described below. The negative side of the operational amplifier 23a is connected between the discharge capacitors 22a and 22b of the backlight drive circuit 22 via a diode 23b and a smoothing capacitor 23c, and the divided voltage value between the discharge capacitors 22a and 22b is connected to the threshold power supply 23d. Compare with threshold voltage. The diode 23b and the smoothing capacitor 23c smooth out the divided voltage between the discharge capacitors 22a and 22b and adjust it to a constant voltage. The threshold voltage of the threshold power source 23d according to an embodiment of the present invention is DC 700 mV to 800 mV. The voltage value of the threshold power supply 23d is not limited to the above value, and is preferably determined in accordance with the characteristics of the power supply circuit.

The output side of the operational amplifier 23a is connected to the microcomputer 12a, and the generation of the AC voltage of the separately excited inverter circuit 20 is stopped based on the leak voltage detection signal output from the operational amplifier 23a. In the embodiment of the present invention, since the separately excited inverter circuit 20 realizes inverter control by the IC circuit, the microcomputer 12a outputs the voltage of the separately excited inverter circuit 20 by stopping the output of the start signal of the IC circuit. Stop. The method of stopping the voltage output of the separately excited inverter circuit 20 is not limited to the above method, and a separately excited inverter circuit stop signal from the microcomputer 12a may be connected to the base of the transistor.

Hereinafter, the voltage flow of the backlight power supply circuit will be illustrated with reference to FIG. When the output voltage is started to be supplied to the backlight 13c via the discharging capacitors 22a, 22b, 22c, and 22d, the half-wave rectification of the positive cycle of the output voltage that is discharged to the discharging capacitors 22a and 22b is divided as a detection voltage. And is smoothed by the diode 23b and the smoothing capacitor 23c and input to the negative side of the operational amplifier 23a. The upper graph in FIG. 4 shows the voltage value input to the negative side of the operational amplifier 23a with respect to time T. Moreover, the voltage value represented by the dotted line in the figure indicates 700 mV. From the figure, between T0 and T1, the detection voltage input to the negative side of the operational amplifier 23a is 700 mV or more. Therefore, the operational amplifier 23a does not output a leakage current detection signal, and the separately excited inverter circuit 20 is a driving voltage. Is output to the transformer 21.

Next, when the value of the detection voltage input to the operational amplifier 23a exceeds 700 mV after the time T1, the operational amplifier 23a outputs a leakage current output signal to the microcomputer 12a. The middle part of FIG. 4 is a diagram showing a leakage current detection signal output by the operational amplifier with respect to time T. When the divided value of the detection voltage falls below 700 mV at time T1, the operational amplifier 23a outputs a leak current detection signal having a predetermined voltage. The voltage value of the leakage current detection signal described above may be determined based on the reception voltage of the microcomputer 12a.

When the microcomputer 12a receives the leak current detection signal, the microcomputer 12a stops the start signal of the IC circuit of the separately excited inverter circuit 20 and stops the current flowing through the transformer 21. The lower part of FIG. 4 is a diagram illustrating the output of the separately excited inverter circuit stop signal output from the feedback control unit with respect to time T. From the figure, when the leak current detection signal output from the operational amplifier 23a exceeds a predetermined value at time T2, the microcomputer 12a outputs a separately excited inverter circuit stop signal for stopping the voltage output of the separately excited inverter circuit 20. To do. As a result, no current flows through the backlight 13c, and it is possible to prevent the substrate from being damaged in advance due to scorching near the backlight 13c due to leakage current.

(3) Summary In the backlight power supply circuit 19 of the present invention, the voltage drop detecting means 23 detects the drop in the output voltage by comparing the output voltage of the backlight with the threshold value 23d, and the leakage current preventing means. 12a stops the voltage supply from the separately excited inverter circuit 20 to the backlight 13c when the voltage drop detecting means 23 detects a drop in the output voltage. Therefore, based on the output voltage of the backlight 13c, the substrate is prevented from being damaged due to the generation of the leakage current, so that the leakage current preventing function can be configured with a simple structure. In addition, the circuit for detecting the leakage current is configured by a commercially available operational amplifier 23a, and the microcomputer 12a for the overvoltage detection circuit is used, so that the circuit can be simplified and easily configured.
Simplify the circuit by using it together with the circuit.

In order to achieve the above object, in the backlight power supply circuit according to claim 2, in the backlight power supply circuit for supplying a predetermined power to the backlight using a separately excited inverter type power supply circuit. ,
The output voltage converted by the separately-excited inverter circuit is output to the backlight using a transformer, and the output voltage is supplied to the backlight. A backlight driving circuit, an overvoltage detection circuit for detecting an overvoltage applied to the backlight, connected in parallel with a negative voltage collector for discharging the negative half-wave, and a negative voltage collector for discharging the positive half-wave; Connected in parallel, the divided voltage of the collector capacitor that discharges the positive half-wave is used as a detection voltage, and the detection voltage is smoothed by a smoothing circuit composed of a diode and a smoothing capacitor. A drop in the detection voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV, and the output voltage is higher than the threshold voltage. If the overvoltage detection circuit detects an overvoltage, the output voltage output to the back-excited inverter circuit to the backlight when the overvoltage detection circuit detects an overvoltage. The feedback control is performed so that the voltage becomes a specified voltage, and when the leak current detection signal is output from the leak current detection circuit, the voltage supply from the separately excited inverter circuit to the backlight is stopped.

In the device according to claim 2 configured as described above, when the voltage drop detecting means detects a drop in the output voltage output to the backlight, the leakage current preventing means is connected to the backlight from the separately excited inverter circuit. Since the voltage supply is stopped, the detection means having a simple structure with low current consumption can be configured.

Further, in the backlight power supply circuit according to claim 2, the voltage drop detecting means may detect a drop in the output voltage by comparing the output voltage with a threshold voltage using an operational amplifier. Good.
In the device configured as described above, the voltage drop detection means detects a drop in the output voltage of the backlight by comparing the output voltage and the threshold voltage using an operational amplifier, so a combination of commercially available circuit elements is combined. In addition, an inexpensive detection means can be configured.

3. The backlight power supply circuit according to claim 2, wherein the backlight power supply circuit includes an overvoltage detection circuit for detecting an overvoltage, and a separately excited inverter based on a signal voltage from the overvoltage detection circuit. A feedback control unit for controlling the circuit, and the leakage current prevention means may stop the output of the voltage of the separately excited inverter circuit by outputting a leakage current detection signal to the feedback control unit. .

In the device configured as described above, the leakage current prevention unit diverts the feedback control unit of the overvoltage detection unit and outputs the leakage current detection signal to the feedback control unit to stop the voltage of the separately excited inverter circuit. Therefore, a part of the feedback control circuit for detecting overvoltage is used, so that the detection means can be configured with a simple structure.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combination to apply. It is disclosed as.

It is a block block diagram of a liquid crystal television. It is a block block diagram of an analog board | substrate. It is a block diagram of the power supply circuit for backlights. It is a figure showing each signal. It is a figure of the conventional power supply circuit for backlights.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Liquid crystal television, 11 ... Digital board, 11a ... Tuner part, 11b ... Video signal processing part, 11c ... Audio | voice signal processing part, 11d ... Bus, 11a1 ... Antenna, 12 ... Control part, 12a ... Microcomputer, 12b ... Recording , 12c: Remote control I / F, 12d: OSD unit, 13 ... Liquid crystal display, 13a ... Drive circuit, 13b ... Liquid crystal panel, 13c ... Backlight, 14 ... Analog substrate, 14a ... Rectifier circuit, 14b ... Main transformer, 14c DESCRIPTION OF SYMBOLS ... Power supply circuit, 14d ... Power supply circuit, 14e ... Power supply circuit, 14b1 ... Primary side coil, 14b2 ... Secondary side coil, 15 ... Speaker, 16 ... Housing, 17 ... Outlet, 18 ... Remote control, 19 ... Backlight Power supply circuit, 20 ... separately excited inverter circuit, 21 ... transformer, 21a ... primary side coil, 21b ... secondary side coil, 21c ... secondary side 22 ... Backlight drive circuit, 22a ... Deletion capacitor, 22b ... Deletion capacitor, 22c ... Deletion capacitor, 22d ... Deletion capacitor, 23 ... Leakage current detection circuit, 23a ... Operational amplifier, 23b ... Diode, 23c ... Smoothing capacitor, 23d ... Power supply for threshold, 24 ... Overvoltage detection circuit

Claims (2)

A digital board that generates a video signal and an audio signal based on the television radio wave received by the tuner unit, and that is controlled by a control unit having a microcomputer;
A liquid crystal display that displays video by transmitting a light source from a backlight based on the video signal;
A speaker that outputs audio based on the audio signal;
An AC power source supplied from an outlet is rectified by a rectifier circuit, converted into a predetermined voltage based on the rectified power source, and the digital substrate and an analog substrate for supplying the converted power source to the liquid crystal display In LCD television,
The analog board is
A separately-excited inverter circuit that converts a voltage required for driving the backlight based on the rectified power source;
The output voltage converted by the separately-excited inverter circuit is output to a discharge capacitor that discharges a positive cycle voltage and a negative discharge capacitor that discharges a negative cycle voltage via a transformer, respectively. A backlight driving circuit to be supplied;
An overvoltage detection circuit for detecting an overvoltage applied to the backlight , connected in parallel with a voltage-dissipating capacitor for discharging the positive cycle voltage ;
The negative cycle voltage is connected in parallel with the voltage-dissipating capacitor, and the voltage of the negative-current capacitor that discharges the negative cycle voltage is used as a detection voltage. The detection voltage is composed of a diode and a smoothing capacitor. After smoothing by a smoothing circuit, a drop in the detected voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV via an operational amplifier , and the output voltage is higher than the threshold voltage. Is also small, it has a leakage current detection circuit that outputs a leakage current detection signal from the operational amplifier,
When the overvoltage detection circuit detects an overvoltage, the microcomputer performs feedback control so that the output voltage output to the backlight drive circuit is set to a specified voltage in the separately excited inverter circuit, and the leakage current detection circuit A liquid crystal television, wherein when a current detection signal is output, control is performed to stop voltage supply from the separately excited inverter circuit to the backlight drive circuit . In a backlight power supply circuit for supplying a predetermined power to a backlight using a separately excited inverter type power supply circuit,
The output voltage converted by the separately-excited inverter circuit is output to a discharge capacitor that discharges a positive cycle voltage and a negative discharge capacitor that discharges a negative cycle voltage via a transformer, respectively. A backlight driving circuit to be supplied;
An overvoltage detection circuit for detecting an overvoltage applied to the backlight, connected in parallel with a voltage-dissipating capacitor for discharging the positive cycle voltage;
The negative cycle voltage is connected in parallel with the voltage-dissipating capacitor, and the voltage of the negative-current capacitor that discharges the negative cycle voltage is used as a detection voltage. The detection voltage is composed of a diode and a smoothing capacitor. After smoothing by a smoothing circuit, a drop in the detected voltage is detected by comparing with a threshold voltage having a value between 700 mV and 800 mV via an operational amplifier, and the output voltage is higher than the threshold voltage. Is also small, it has a leakage current detection circuit that outputs a leakage current detection signal from the operational amplifier,
When the overvoltage detection circuit detects an overvoltage, feedback control is performed so that the output voltage output to the backlight is set to a specified voltage to the separately excited inverter circuit, and a leakage current detection signal is output from the leakage current detection circuit. If it is, a power supply circuit for a backlight , wherein the voltage supply from the separately excited inverter circuit to the backlight is stopped .