JP2010193639A - Power supply inspection circuit and display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply inspection circuit capable of individually changing a process depending on the life of an article, relating to a plurality of circuits constituting a power supply circuit. <P>SOLUTION: A power supply inspection circuit which determines article life of a plurality of power supply circuits includes a ripple component detecting part for detecting a ripple component of DC voltage supplied from the power supply circuit, a selection part which switches connection to the plurality of power supply circuits or to the ripple component detecting part and selects a power supply circuit 80 of which ripple component has been detected, and a process control part which individually determines article life of respective poser supply circuits according to the detected ripple component, and changes a process for the power supply circuit thereafter according to the selected power supply circuit. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a power supply inspection circuit for detecting a life in a power supply circuit.

  The power supply circuit is equipped with a capacitor for smoothing. When this capacitor deteriorates, the power supply voltage is not smoothed properly, and the value of the generated power supply voltage decreases. For this reason, a technique for detecting the decrease in the voltage value and detecting the product life of the power supply circuit is known (see, for example, Patent Document 1).

  Further, the deterioration of the smoothing capacitor causes a ripple component to be superimposed on the DC component of the power supply voltage. Therefore, a technique for detecting the product life of the power supply circuit by detecting the ripple component has been disclosed (see, for example, Patent Documents 2-4).

JP 2002-281735 A Japanese Patent Laid-Open No. 2001-231253 Japanese Patent Laid-Open No. 10-164836 Japanese Patent Laid-Open No. 08-248086

  The power supply circuit is configured to include circuits that generate various voltages, and it is preferable that each circuit also changes the corresponding processing according to the degree of deterioration. In other words, it is desirable to change the processing for each power supply circuit because there are circuits that need to stop driving as soon as the power supply circuit deteriorates, and circuits that have no safety problems even after a certain period of time. .

  An object of the present invention is to provide a power supply inspection circuit capable of individually changing the processing of a plurality of circuits constituting a power supply circuit according to the product life.

  In order to solve the above-described problems, in the present invention, in a power supply inspection circuit that determines product lifetimes for a plurality of power supply circuits, a ripple component detection unit that detects a ripple component of a DC voltage generated by the power supply circuit, and the plurality of power supplies The connection between the circuit and the ripple component detection unit is switched, the selection unit for selecting the power supply circuit in which the ripple component is detected, and the product life of each power supply circuit individually according to the detected ripple component A processing control unit that determines and changes processing for the subsequent power supply circuit in accordance with the selected power supply circuit.

In the invention configured as described above, in the power supply inspection circuit that determines the product life for a plurality of power supply circuits, the ripple component detection unit detects a ripple component of the DC voltage generated by the power supply circuit, and the selection unit includes a plurality of selection units. By switching the connection between the power supply circuit and the ripple component detector, the power supply circuit that detects the ripple component is selected, and the processing control means determines the product life of each power supply circuit based on the voltage value of the detected ripple component. Individual determination is made, and processing for subsequent power supply circuits is changed in accordance with the selected power supply circuit.
Therefore, since the subsequent processing is changed according to the power supply circuit in which the product life is detected, it is possible to take individual measures according to the predetermined power supply circuit in accordance with the detected product life.

Further, as one aspect of the present invention, the ripple component detection unit extracts a ripple component from the generated DC component, amplifies the extracted ripple component, smoothes the amplified ripple component, and performs the processing control. To the output.
Since the ripple component includes an AC component, it is not suitable as a detection target as it is. Therefore, in the invention configured as described above, the extracted ripple component is converted into a component that can be determined by the processing control unit and output.

And as one situation of the present invention, the processing control part changes the amplification factor of the ripple component in the ripple component detection part according to the selected power supply circuit.
In the power supply circuit, the smoothing capacitor has a different capacity due to a difference in generated voltage and the like, and thus the generated ripple component value is also different. Therefore, in the invention configured as described above, the processing control unit can make a determination using a uniform value by changing the amplification factor of the ripple component according to each power supply circuit to a uniform value. It becomes possible. Moreover, if the value after the change of the ripple component becomes a uniform value, it becomes possible to receive the ripple component input from a plurality of power supply circuits via one input port, and the processing control unit is made compact. Can do.

Further, as an example of the process executed by the process control unit, the process control unit includes a display unit for displaying an error message when the product life of the power supply circuit is determined.
In the invention configured as described above, the product life of the power supply circuit can be visually notified to the user.

  Furthermore, the display unit may be configured to switch the error message according to the value of the detected ripple component.

As an example of processing performed by the processing control unit, the power supply circuit includes a primary power supply circuit, and the processing control unit determines that the primary power supply circuit is selected and the product life has been reached. If this happens, the driving of the primary power supply circuit is immediately stopped.
Further, the power supply circuit includes a converter circuit for driving a backlight, and the processing control unit immediately selects the converter circuit when the converter circuit is selected and it is determined that the product life has been reached. Stop driving the circuit.
In the invention configured as described above, in a power supply circuit such as a primary-side power supply circuit or a converter circuit that requires safety as important, if the product life has been reached, the drive is immediately stopped to improve safety. Increase. Here, the converter circuit is a circuit that generates a driving voltage for driving the backlight, and is a concept including a DC-DC converter circuit and an inverter circuit.

  Further, as an example of processing performed by the processing control unit, the processing control unit is defined based on a ripple component when a value of the detected ripple component is not deteriorated in a smoothing capacitor mounted on the power supply circuit. If the smoothing capacitor mounted on the power supply circuit is deteriorated and is less than the second threshold defined based on the ripple component, an error message is displayed on the display unit. When the value of the received ripple component is equal to or greater than the second threshold, it is determined that the power supply circuit has reached the product life, and the driving of the power supply circuit is stopped.

Further, the processing control unit may store a value based on the input ripple component.
In the invention configured as described above, by storing a value based on the detected ripple component, it is possible for a service person or the like to easily determine the life of the power supply circuit with reference to the stored value. Become.

  As another aspect of the present invention, in a display device for displaying an image using a liquid crystal panel, a primary side power supply circuit, a power supply circuit including a converter circuit for lighting a backlight, and the primary side power supply A power supply inspection circuit that determines a product life for a circuit, a converter circuit, and other power supply circuits, wherein the power supply inspection circuit extracts a ripple component from a DC voltage generated by the power supply circuit, and the extracted ripple A ripple component detection unit that amplifies the component and smoothes the amplified ripple component to generate a life detection signal; a switching unit that switches connection between the power supply circuit and the ripple component detection unit; and a generated lifetime A microcomputer for receiving a detection signal and determining the product life of each circuit constituting the power supply circuit; In addition, the amplification factor of the ripple component in the ripple component detection unit is changed according to the selected power supply circuit, and the selected power supply circuit is a power supply circuit other than the primary power supply circuit and the converter circuit, When the voltage value of the received life detection signal is less than a first threshold defined based on a ripple component when the smoothing capacitor mounted on the selected power supply circuit is not deteriorated, A value based on the life detection signal is stored in a memory, and the selected power supply circuit is a power supply circuit other than the primary power supply circuit and the converter circuit, and the voltage value of the received life detection signal is equal to or greater than the first threshold value. And less than a second threshold defined based on the ripple component when the smoothing capacitor mounted on the selected power supply circuit is deteriorated. An error message is displayed on the liquid crystal panel, and the selected power supply circuit is a power supply circuit other than the primary power supply circuit and the converter circuit, and the voltage value of the received life detection signal is the second threshold value. If it is above, it is determined that the selected power supply circuit has reached the product life, the drive of the selected power supply circuit is stopped, and the selected power supply circuit is a primary power supply circuit or a converter circuit. The voltage value of the received life detection signal is not less than a third threshold value defined based on a ripple component when the smoothing capacitor mounted on the primary side power supply circuit or the converter circuit is not deteriorated. In this case, the driving of the selected primary side power supply circuit or converter circuit is stopped.

  According to the present invention configured as described above, it is possible to provide a power supply inspection circuit capable of taking appropriate measures for a power supply circuit whose life has been detected.

It is a block diagram for demonstrating the structure of a display apparatus. It is an image figure for demonstrating the function of a display apparatus. 3 is a block diagram for explaining a configuration of a power supply circuit 80. FIG. 3 is a block diagram for explaining a configuration of a control circuit 70. FIG. It is a wave form diagram explaining the process in which a lifetime detection signal is produced | generated. It is a wave form diagram explaining the process in which a lifetime detection signal is produced | generated. It is a wave form diagram explaining the process in which a lifetime detection signal is produced | generated. It is a wave form diagram explaining the process in which a lifetime detection signal is produced | generated. 3 is a flowchart for explaining processing executed by a control circuit 70. It is a block diagram for demonstrating the structure of the power supply circuit 80 which concerns on 2nd Embodiment as an example. It is a block diagram for demonstrating the structure of the control circuit 70 which concerns on 2nd Embodiment as an example. It is a block block diagram explaining the power supply inspection circuit which concerns on 3rd Embodiment.

Hereinafter, the best mode for carrying out the present invention will be described in the following order with reference to the drawings.
1. First embodiment:
2. Second embodiment:
3. Third embodiment:
4). Other embodiments:

1. First embodiment:
FIG. 1 is a block diagram for explaining a configuration of a display device. In FIG. 1, the display device 100 includes an input I / F 91, a display panel 93, a control circuit 70, a signal processing circuit 92, and a power supply circuit 80. The input I / F 91 and the signal processing circuit 92 are connected to the control circuit 70 via the bus 96 and receive control from the control circuit 70 via the bus 96. In the display device 100, the video data acquired through the input I / F 91 is subjected to signal processing such as color correction by the signal processing circuit 92, and then output as video by the display panel 93. Further, the display device 100 receives the AC or DC voltage generated by the power supply circuit 80 via the power supply line, and drives each unit.

  The input I / F 91 is connected to an external device such as a recording / playback device, and includes an external input terminal that receives video and audio signals, a tuner that extracts a television broadcast signal from a broadcast wave received by an antenna, and the like. Yes.

  The display panel 93 includes a liquid crystal display unit 95 for displaying a color image, and a backlight 94 that functions as a light source for the liquid crystal display unit. Further, the liquid crystal display unit 95 has a drive circuit for driving each pixel, and generates a drive voltage for driving each pixel using a power supply voltage of a predetermined voltage output from the power supply circuit 80. To do.

  The power supply circuit 80 is connected to each part constituting the display device 100 via a power supply line, and supplies power to each of the above parts. A specific configuration of the power supply circuit 80 will be described later.

  The control circuit 70 controls the driving of each part constituting the display device 100, detects the ripple component of the power supply circuit 80, stops the power supply circuit 80 according to the detected ripple component, or supplies power to the user through the display panel 93. Notify that the circuit 80 is at the end of its life. Here, in the present invention, the control circuit 70 determines the product life of the power supply circuit 80 based on the deterioration of the smoothing capacitor mounted therein. Specifically, when the smoothing capacitor deteriorates, a ripple component is generated in the generated DC voltage. Therefore, the control circuit 70 determines the deterioration of the smoothing capacitor by detecting this ripple component, and thus determines the product life of the power supply circuit 80.

  FIG. 2 is an image diagram for explaining the function of the display device. As illustrated in FIG. 2, the display device detects a ripple component of the power supply circuit 80 and executes the following processing. First, as a first process, the control circuit 70 stores the detected ripple component value of the power supply circuit 80 in a memory such as the EEPROM 97. The value of the ripple component stored in the memory is used when a serviceman or the like determines the state of the display device 100. Next, when the detected ripple component has reached a certain value, the control circuit 70 displays an error message on the display panel 93 as the second processing. When it is determined that the product life of the power supply circuit 80 has expired due to the ripple component, the control circuit 70 stops driving the power supply circuit 80 as a third process. Below, the 1st-3rd process performed by the control circuit 70 is demonstrated.

  FIG. 3 is a block diagram for explaining the configuration of the power supply circuit 80. FIG. 4 is a block diagram for explaining the configuration of the control circuit 70. In FIG. 3, the power supply circuit 80 includes a primary power supply circuit 81 and a plurality of secondary power supply circuits 60. The primary side power supply circuit 81 and the secondary side power supply circuit 60 are connected via a switch SW, and the on / off of the switch SW is switched by the control circuit 70. Further, the primary side power supply circuit 81 and the secondary side power supply circuit 60 are respectively connected to the control circuit 70.

  The primary side power supply circuit 81 includes a rectifier circuit 81a and a smoothing circuit 81b, and converts an AC voltage supplied from a commercial power source into a DC voltage by the rectifier circuit 81a and the smoothing circuit 81b. To the side power supply circuit 60.

  The secondary power supply circuit 60 boosts or steps down the DC voltage supplied from the primary power supply circuit 81 to generate a DC voltage. The secondary power supply circuit 60 includes a switching circuit 60a and a smoothing circuit 60b, and generates a power supply voltage required by the display panel 93, the control circuit 70, and the signal processing circuit 92. Further, the smoothing circuit 60b includes a smoothing capacitor, and the output side of the smoothing circuit 60b is connected in parallel with a switching circuit 71 (described later) of the control circuit 70. In the present embodiment, as the secondary power supply circuit 60, a converter circuit 61 that supplies a power supply voltage to the backlight 94 and a drive voltage generation circuit 62 that supplies a drive voltage generation signal to the display panel 93 are used. The present invention will be described.

  In FIG. 4, the control circuit 70 is connected to the secondary power supply circuit 60 and determines the product life of each power supply circuit 80. The control circuit 70 includes a switching circuit (selection unit) 71 that switches the connection state between the secondary power supply circuits 60, a ripple detection circuit (ripple component detection unit) 72 that extracts a ripple component from the input power supply voltage, and the like. The microcomputer (processing control unit) 73 changes the subsequent processing in accordance with the extracted ripple component value.

  The switching circuit 71 is constituted by, for example, a semiconductor switch, and is connected to each secondary power supply circuit 60 on the input side and is connected to the ripple detection circuit 72 on the output side. The switching circuit 71 switches between input and output in accordance with a switching signal output from the microcomputer 73. This switching signal is input by an operation via a preset program or a user's remote control.

  The ripple detection circuit 72 extracts a ripple component from the power supply voltage output from the output terminal of the switching circuit 71, and generates a life detection signal from the ripple component. The ripple detection circuit 72 includes a capacitor 72a that extracts a ripple component from a power supply voltage, an amplification circuit 72b that amplifies the extracted ripple component, and a rectifier circuit 72c that rectifies the amplified ripple component. .

  5, 6, 7, and 8 are waveform diagrams illustrating a process in which a life detection signal is generated. The ripple detection circuit 72 uses the capacitor 72a to offset the DC component of the power supply voltage (FIG. 5) input via the output terminal of the switching circuit 71 and extracts the ripple component (FIG. 6).

  Next, the ripple detection circuit 72 amplifies the amplitude of the ripple component by the amplification circuit 72b (FIG. 7). Here, since the ripple component generated due to a difference in the capacity of the smoothing capacitor or the like differs depending on the power supply circuit 80, the amplifier circuit 72b changes the ripple component amplification factor depending on the power supply circuit 80, thereby generating the ripple. It is possible to amplify the components and uniformize the object that the control circuit 70 determines. In addition, the input port of the control circuit 70 can be configured with one system, and the circuit scale can be reduced.

  Then, the ripple detection circuit 72 smoothes the amplified ripple component by the rectifier circuit 72c, generates a life detection signal, and outputs it to the input terminal of the microcomputer 73 (FIG. 8).

  The microcomputer 73 switches the switching circuit 71 in order to detect the product life of the predetermined power supply circuit 80, and outputs an amplification factor setting signal for changing the amplification factor of the amplifier circuit 72b in accordance with the selected power supply circuit 80. . Further, the microcomputer 73 selects the above first to third processes according to the value of the life detection signal input from the power supply circuit for detecting the life and the ripple detection circuit 72 and controls each part.

  The microcomputer 73 includes a CPU 73a that executes predetermined calculations, a ROM 73b that stores programs and data for the CPU 73a to execute predetermined calculations, a RAM 73c that functions as a work area for the CPU 73a, and an input An A / D conversion circuit 73d that converts the life detection signal from analog to digital and outputs the converted signal to the CPU 73a and an OSD circuit 73e for displaying a predetermined OSD screen on the display panel 93 are provided.

  The ROM 73b stores a program for the CPU 73a to detect the product life of each power supply circuit 80. Therefore, the CPU 73a executes the first to third processes by executing the program under a predetermined operation system.

  FIG. 9 is a flowchart for explaining processing executed by the control circuit 70. The control circuit 70 detects the product life of the power supply circuit 80 according to the flow shown in FIG. 9, and executes the subsequent processing.

  The microcomputer 73 outputs a switching signal to the switching circuit and switches the power supply circuit 80 that detects the product life (step S110). In the flowchart shown in FIG. 9, the response after the product life is detected is different in the converter circuit 61 and the other power supply circuit 80 in the secondary power supply circuit 60.

  Further, the microcomputer 73 outputs a switching signal and sets the amplification factor of the ripple component corresponding to the selected power supply circuit 80 (step S120). For example, since the converter circuit 61 and the other power supply circuit have different smoothing capacitor capacities, the microcomputer 73 outputs an amplification factor setting signal so as to set a corresponding amplification factor for the amplifier circuit 72b.

  The ripple detection circuit 72 generates a life detection signal from the input power supply voltage (step S130). Therefore, an analog life detection signal corresponding to the power supply circuit 80 selected by the switching signal is input to the A / D conversion circuit of the microcomputer 73.

  The microcomputer 73 compares the generated life detection signal with a threshold value, and changes subsequent processing according to the comparison result (steps S140 to S220). The A / D conversion circuit 73d converts the life detection signal from analog to digital and inputs it to the CPU 73a. The CPU 73a compares the voltage of the life detection signal with a threshold while referring to the table developed in the RAM 73c. Hereinafter, as a power supply circuit 80 other than the inverter circuit 61, life detection for the drive voltage generation circuit 62 and subsequent processing will be described.

  When the life detection signal of the drive voltage generation circuit 62 (hereinafter simply referred to as the life detection signal D1) is equal to or less than the threshold value S1 (step S150), the microcomputer 73 sets the value of the life detection signal D1 at this time to the EPROM 97. Etc. (step S160), and the product life detection process is terminated. The threshold value S1 is a value based on a ripple component when the smoothing capacitor of the drive voltage generation circuit 62 is not deteriorated at all. When the life detection signal D1 is equal to or less than the threshold value S1, the microcomputer 73 generates the drive voltage. The circuit 62 determines that the product life has not been reached.

  At this time, the storage of the detected life detection signal D1 in the EPROM 97, which is executed by the microcomputer 73 (first process: step S160), is used by a serviceman or the like to determine the state of the display device.

  If the life detection signal is not less than the threshold value S1 and less than the threshold value S2 (step S170), the microcomputer 73 displays an error message on the display panel 93 through the OSD circuit 73e (step S180). The threshold value S2 is a value based on a ripple component when the smoothing capacitor of the drive voltage generation circuit 62 has deteriorated to such an extent that it does not perform a function at the time of design, and the life detection signal is equal to or greater than the threshold value S1. If it is less than S2, the microcomputer 73 displays an error message on the display panel 93 in order to prompt the user to replace the drive voltage generation circuit 62, although the drive voltage generation circuit 62 has not reached the product life. As an example of the error message, the name of the power supply circuit whose life has been detected, the voltage value of the life detection signal, and the like are displayed. Further, the life detection signal at this time is also stored in the EEPROM 97.

  Further, when the life detection signal D1 is equal to or greater than the threshold value S2, the microcomputer 73 immediately stops driving the drive voltage generation circuit 62 (step S190). Specifically, the microcomputer 73 switches the switch SW to cut off the power supplied from the primary side power supply circuit 81 to the drive voltage generation circuit 62. Therefore, the drive voltage generation circuit 62 stops driving. At this time, a display indicating that driving is stopped may be displayed on the display panel 93 as an error message.

  Next, the life detection of the converter circuit 61 and the subsequent processing will be described. When the converter circuit 61 is reaching the end of its life, the display device 100 is configured to stop driving the converter circuit 61 in consideration of safety and the like.

  When the life detection of the converter circuit 61 is selected by the switching signal in step S110, the microcomputer 73 compares the life detection signal of the converter circuit 61 (hereinafter simply referred to as the life detection signal D2) with the threshold S3 ( Step S200). The threshold value S3 is a value determined based on a ripple component when the smoothing capacitor of the converter circuit 61 does not perform the function at the time of design.

  Therefore, if the life detection signal D2 is less than the threshold value S3, the microcomputer 73 stores the voltage value of the life detection signal in the EEPROM 97 (step S160), and ends the product life detection process. If the life detection signal D2 is greater than or equal to the threshold value S3, the microcomputer 73 immediately stops the converter circuit 61 (step S210). Specifically, the microcomputer 73 stops the start signal output to the converter circuit 61 and stops driving the converter circuit 61. Thereafter, the microcomputer 73 displays an error message on the display panel 93 (step S220), and stores the value of the lifetime detection signal D2 at that time in the EEPROM 97. The first embodiment has been described above.

2. Second embodiment:
The target for detecting the lifetime is not limited to the secondary power supply circuit 60, and the primary power supply circuit 81 may be included in the detection target. FIG. 10 is a block diagram for explaining a configuration of a power supply circuit 80 according to the second embodiment as an example. FIG. 11 is a block diagram for explaining the configuration of the control circuit 70 according to the second embodiment as an example.

  In the configuration shown in FIG. 10, in addition to the circuit configuration shown in FIG. 3, the output side of the primary side power supply circuit 81 is connected in parallel with the secondary side power supply circuit 60 and the control circuit 70. Therefore, the power supply voltage from the primary side power supply circuit 81 is output to the control circuit 70, and the ripple component is detected.

  In addition to the circuit configuration shown in FIG. 4, the control circuit 70 shown in FIG. 11 includes a capacitor 72 a and an amplifier circuit as a ripple detection circuit 72 that generates a life detection signal from the power supply voltage output from the primary power supply circuit 81. 72b, a rectifier circuit 72c, and a photocoupler 72d for outputting the generated life detection signal to the microcomputer 73. Further, in the control circuit 70 shown in FIG. 11, in addition to the circuit configuration shown in FIG. 4, a life detection signal generated based on the power supply voltage output from the secondary power supply circuit 60 and the primary power supply circuit 81. And a second switching circuit 74 for switching to any one of the life detection signals generated based on the power supply voltage and outputting to the A / D conversion circuit 73d.

  Therefore, the power supply voltage from the primary side power supply circuit 81 is converted into an analog life detection signal by the capacitor 72a, the amplifier circuit 72b, and the rectifier circuit 72c, and then output to the control circuit 70 via the photocoupler 72d. In FIG. 10, the amplification factor of the amplifier circuit 72b connected to the primary power supply circuit 81 is a fixed value, but the present invention is not limited to this. The microcomputer 73 controls the switching circuit 71 and the second switching circuit 74 so that the life detection signal based on the power supply voltage from the primary power supply circuit 81 and the life detection signal based on the power supply voltage from the secondary power supply circuit 60 are obtained. Is output to the A / D conversion circuit 73d.

  Further, when the microcomputer 73 receives the digital life detection signal via the A / D conversion circuit 73d, the microcomputer 73 immediately stops the driving of the primary power supply circuit 81. Therefore, in addition to the function of the display device 100 according to the first embodiment, when the life detection signal output from the primary power supply circuit 81 is equal to or greater than a predetermined threshold, in addition to the error display, the primary power supply circuit The drive of 81 is stopped.

3. Third embodiment:
FIG. 12 is a block diagram illustrating a power supply inspection circuit according to the third embodiment. In the second embodiment, an inspection system 120 including a display device 100 and an inspection device 110 for inspecting the display device 100 will be described. The inspection device 110 performs product inspection at the time of shipment of the display device 100 from the factory. Further, as a part of the function, the state of the smoothing capacitor is determined according to the life test signal output from the display device 100, and an error display or a ripple component determined from the life test signal is determined according to the determination result. Displays the value of.

  The inspection device 110 includes an input I / F 111 for connecting to the display device 100, a control circuit 112, and a display unit 113, and the life detection signal output from the display device 100 is input to the input I / F 111. The control circuit 112 receives the error message, and displays an error message or the like on the display unit 113 according to a predetermined calculation result.

  When the display device 100 is shipped, the inspection device 110 determines whether a smoothing capacitor of each power supply circuit 80 is erroneously attached or the like according to a life detection signal output from the display device 100. That is, when the smoothing capacitor of the power supply circuit 80 is misassembled or the smoothing capacitor is defective, the smoothing capacitor does not function, and the ripple component of the power supply voltage often exceeds a predetermined value. . Therefore, the inspection apparatus 110 determines the state of each smoothing capacitor based on the life detection signal, and displays an error display on the display unit 113 and the amplitude of the ripple component determined from the life inspection signal according to the determination result.

4). Other embodiments:
There are various modifications of the present invention.
That is, the configuration for extracting the ripple component is an example, and the configuration for extracting the ripple component may be other configurations.
In addition, the period in which the microcomputer 73 detects the life detection signal can be arbitrarily set. For example, the period in which the microcomputer 73 detects the life signal may be every year, every month, and every day. In this case, in step S160 in FIG. 9, each detected life detection signal is stored in the EEPROM 97 as a detection history, so that when a serviceman or the like conducts an inspection, the detection history is referred to by referring to this detection history. It becomes easy to judge the lifetime.

  60 ... Secondary power supply circuit, 60a ... Switching circuit, 60b ... Smoothing circuit, 61 ... Converter circuit, 62 ... Drive voltage generation circuit, 70 ... Control circuit, 71 ... Switching circuit, 72 ... Ripple detection circuit, 72a ... Capacitor 72b ... amplifier circuit, 72c ... rectifier circuit, 73 ... microcomputer, 73a ... CPU, 73b ... ROM, 73c ... RAM, 73d ... A / D converter circuit, 73e ... OSD circuit, 80 ... power supply circuit, 81 ... primary side Power supply circuit, 81a ... rectifier circuit, 81b ... smoothing circuit, 91 ... input I / F, 92 ... signal processing circuit, 93 ... display panel, 94 ... backlight, 95 ... liquid crystal display unit, 96 ... bus, 100 ... display 110, inspection device, 111, input I / F, 112, control circuit, 113, display unit, 120, inspection system

Claims (10)

In the power supply inspection circuit that determines the product life for multiple power supply circuits,
A ripple component detector that detects a ripple component of a DC voltage generated by the power supply circuit;
A selector that switches connection between the plurality of power supply circuits and the ripple component detector, and that selects the power supply circuit in which the ripple component is detected;
A process control unit that individually determines a product life of each of the power supply circuits according to the detected ripple component, and changes a process for the subsequent power supply circuit according to the selected power supply circuit. Power supply inspection circuit.   The ripple component detection unit extracts a ripple component from the DC voltage, amplifies the extracted ripple component, smoothes the amplified ripple component, and outputs the smoothed ripple component to the processing control unit. Item 4. The power supply inspection circuit according to Item 1.   The power supply inspection circuit according to claim 2, wherein the processing control unit changes an amplification factor of the ripple component in the ripple component detection unit in accordance with the selected power supply circuit.   The said process control part has a display part for displaying an error message, when the product lifetime of the said power supply circuit is judged, The Claim 1 characterized by the above-mentioned. Power supply inspection circuit.   5. The power supply inspection circuit according to claim 1, wherein the display unit switches the error message in accordance with a value of the detected ripple component. The power supply circuit includes a primary power supply circuit,
2. The processing control unit, when it is determined that the primary power supply circuit is selected and the product life is reached, immediately stops driving the primary power supply circuit. The power supply inspection circuit according to claim 5. The power supply circuit includes a converter circuit for driving a backlight,
The processing control unit immediately stops the driving of the converter circuit when it is determined that the converter circuit is selected and the product life has been reached. The power supply inspection circuit according to any one of the above. The processing control unit
The value of the detected ripple component is equal to or greater than a first threshold value defined based on the ripple component when the smoothing capacitor mounted on the power supply circuit is not deteriorated, and the smoothing mounted on the power supply circuit If the capacitor is less than the second threshold specified based on the ripple component when the capacitor is deteriorated, an error message is displayed on the display unit,
The drive of the power supply circuit is stopped when it is determined that the power supply circuit has reached the product life when the value of the received ripple component is equal to or greater than the second threshold value. The power supply inspection circuit according to claim 7.   The power supply inspection circuit according to claim 1, wherein the processing control unit stores a value based on the input ripple component. In a display device for displaying an image using a liquid crystal panel,
A power circuit including a primary power circuit and a converter circuit for turning on the backlight;
A power supply inspection circuit for determining the product life for the primary side power supply circuit, the converter circuit and other power supply circuits,
The power supply inspection circuit is
A ripple component detection unit that extracts a ripple component from the DC voltage generated by the power supply circuit, amplifies the extracted ripple component, and smoothes the amplified ripple component to generate a life detection signal;
A switching unit that switches connection between the power supply circuit and the ripple component detection unit;
A microcomputer that receives the generated life detection signal and determines the product life of each circuit constituting the power supply circuit;
The microcomputer is
According to the selected power supply circuit, while changing the amplification factor of the ripple component in the ripple component detection unit,
The selected power supply circuit is a power supply circuit other than the primary side power supply circuit and the converter circuit, and a voltage value of the received life detection signal is deteriorated in a smoothing capacitor mounted on the selected power supply circuit. If it is less than the first threshold value defined based on the ripple component in the absence, the value based on the life detection signal is stored in the memory,
The selected power supply circuit is a power supply circuit other than the primary side power supply circuit and the converter circuit, and the voltage value of the received life detection signal is equal to or higher than the first threshold value, and is mounted on the selected power supply circuit. If the smoothing capacitor is less than the second threshold specified based on the ripple component in the case of deterioration, an error message is displayed on the liquid crystal panel,
When the selected power supply circuit is a power supply circuit other than the primary side power supply circuit and the converter circuit, and the voltage value of the received life detection signal is not less than the second threshold value, the selected power supply circuit is Judging that the product life has been reached, the drive of the selected power supply circuit is stopped,
The selected power supply circuit is a primary side power supply circuit or converter circuit, and the voltage value of the received life detection signal is not deteriorated in the smoothing capacitor mounted on the primary side power supply circuit or converter circuit. A display device characterized by stopping driving of the selected primary side power supply circuit or converter circuit when the threshold value is equal to or greater than a third threshold value defined based on a ripple component.

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