KR20060086544A - Lamp driving device and liquid crystal display device having the same - Google Patents

Abstract

Disclosed are a lamp driving device capable of detecting a defect and a liquid crystal display device having the same.

The lamp driving apparatus of the present invention includes a backlight having a plurality of lamps, an inverter generating a driving voltage to be supplied to the plurality of lamps, a plurality of connecting lines branched between the inverter and the backlight to supply a driving voltage, and the plurality of lamps. And a failure detecting unit configured to sense a driving voltage supplied to the lamp of the lamp and to control the shutdown of the inverter according to the detection result.

Lamp drive, electrode leads, shut-down

Description

Lamp driving device and liquid crystal display device having same {Lamp driving device and Liquid Crystal Display device having the same}

1 is an exploded perspective view of a backlight of a conventional liquid crystal display.

2 is a view showing the lamp and the lamp driving device of FIG.

3 is a view showing a liquid crystal display device according to the present invention.

4 is a view illustrating in detail a lamp driving device and a backlight of the liquid crystal display of FIG.

5 illustrates the logic of the OR gate of FIG.

<Brief description of the main parts of the drawing>

101a, 101b: first and second lamps 102: liquid crystal panel

104: gate driver 106: data driver

108: backlight 109: electrode connection line

110: timing controller 112: backlight drive unit

113: inverter 114: first sensor unit

115: defective detection unit 116: second sensor unit

117: OR gate 119: Shut down control unit

The present invention relates to a liquid crystal display device, and more particularly, to a lamp driving device capable of detecting a defect and a liquid crystal display device having the same.

In liquid crystal display devices, two substrates on which electrodes are formed are disposed so that the surfaces on which the two electrodes are formed face each other, a liquid crystal material is injected between the two substrates, and a liquid crystal is generated by an electric field generated by applying a voltage to the two electrodes. By displacing molecules, the image is expressed by the transmittance of light that varies accordingly.

1 is an exploded perspective view of a backlight of a conventional liquid crystal display.

As shown in FIG. 1, the backlight includes a plurality of lamps 1, an outer case 3 for fixing and supporting the plurality of lamps 1, the lamp 1 and a liquid crystal panel (not shown). ) And optical sheets 5a, 5b, and 5c disposed therebetween. It includes a plurality of diffusion sheet and the like provided between the liquid crystal panel to enhance the light scattering effect. The inner surface of the outer case 3 is formed with a reflector 7 for reflecting the light generated by the lamp 1 to the display unit of the liquid crystal panel to increase the efficiency of the light.

2 is a view showing the lamp and the lamp driving device of FIG.

As shown in FIG. 2, the first and second lamps 1a and 1b are disposed at both ends of the inside of the glass tube so that the electrodes are disposed to emit light by an AC power applied to the electrodes. Both ends of the two lamps 1a and 1b are fitted in grooves formed on both sides of the outer case 3 of FIG. In addition, first and second electrode connection lines 9a and 9b for transmitting power for driving the lamp are connected to the electrodes of the first and second lamps 1a, and the first and second electrode connection lines 9a, 9b) is electrically connected to the inverter 14.

The first and second lamps 1a and 1b and the inverter 14 are connected by first and second electrode connection lines 9a and 9b, respectively. That is, the AC voltage generated by the inverter 14 is supplied to the first and second lamps 1a and 1b through the second electrode connection line 9b. The first and second lamps 1a and 1b emit light by generating a tube current using the AC voltage. The first electrode connecting line 9a is grounded, and the second electrode connecting line 9b is connected to the inverter 14.

While the AC voltage generated in the inverter 14 is supplied to the first and second lamps 1a and 1b through the second electrode connection line 9b, the second electrode connection line 9b is opened, that is, The case of disconnection occurs. For example, when the AC voltage generated by the inverter 14 is a voltage having a large load, when the AC voltage is supplied to the second electrode connection line 9b, the second electrode connection line 9b may be cut off. Can be. In addition, the second electrode connecting line 9b is opened due to a defect that is not detected in the process of manufacturing the second electrode connecting line 9b, so that the AC voltage generated by the inverter 14 is changed to the first and second. It is not supplied to the lamps 1a and 1b.

Even when the second electrode connecting line 9b connected to the first lamp 1a is opened, the AC voltage generated by the inverter 14 is supplied to the second lamp 1b so that the second lamp 1b is It generates a tube current and emits light. Of course, this case means that the second electrode connecting line 9b connected to the second lamp 1b is not opened.                         

That is, even though the second electrode connecting line 9b connected to the first lamp 1a is opened and the AC voltage generated by the inverter 14 is not supplied to the first lamp 1a, the second lamp 1b When the second electrode connecting line 9b connected to the second electrode 1b is not opened, the second lamp 1b emits light. Even if the first lamp 1a does not emit light, the second lamp 1b emits light, so that the second electrode connecting line 9a connected to the first lamp 1a is not detected. That is, it is not detected that the second lamp 1b emits light and the first lamp 1a does not emit light.

It is urgent to develop a liquid crystal display device capable of detecting a defect in advance before a consumer purchases the liquid crystal display device having such a defect.

It is an object of the present invention to provide a lamp driving device capable of detecting a defect and a liquid crystal display device having the same.

A lamp driving apparatus according to an embodiment of the present invention for achieving the above object is a backlight having a plurality of lamps, an inverter for generating a driving voltage to be supplied to the plurality of lamps, the branch and driving between the inverter and the backlight A plurality of connection lines for supplying a voltage and a failure detection unit for detecting a driving voltage supplied to the plurality of lamps, and to control the shutdown (shut down) of the inverter according to the detection result.

A liquid crystal display according to an embodiment of the present invention for achieving the above object is a backlight having a plurality of lamps, an inverter for generating a driving voltage supplied to the plurality of lamps, branched between the inverter and the backlight and the And a fail detection unit configured to sense driving voltages supplied to a plurality of lamps and control shutdown of the inverter according to a detection result, and a liquid crystal panel to display an image according to light emitted from the backlight.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

3 is a view showing a liquid crystal display device having a lamp driving device according to the present invention.

As shown in FIG. 3, the liquid crystal display includes a liquid crystal panel 102 displaying predetermined data, a gate driver 104 and a data driver 106 for driving the liquid crystal panel 102, and A timing controller 110 for controlling the gate driver 104 and the data driver 106, a backlight driver 112 for controlling a lamp and generating a driving voltage for driving the lamp, and the backlight driver 112. It includes a backlight 108 having a plurality of lamps to emit light using a driving voltage generated by the.

The liquid crystal panel 102 includes a plurality of gate lines and a plurality of data lines. A thin film transistor TFT and a pixel electrode connected to the thin film transistor TFT are provided at an intersection of the plurality of gate lines and the plurality of data lines provided on the liquid crystal panel 102. The scan signals generated by the gate driver 104 are supplied to the plurality of gate lines, and the data signals generated by the data driver 106 are supplied to the plurality of data lines. Predetermined data is displayed on the liquid crystal panel 102 due to the scan signal and the data signal.

The gate driver 104 generates a scan signal in response to the gate control signal generated from the timing controller 110. The scan signal is sequentially supplied to a plurality of gate lines provided in the liquid crystal panel 102. When the scan signal is supplied to the plurality of gate lines, the thin film transistor TFT connected to the plurality of gate lines is turned on.

The data driver 106 generates a data signal in response to the data control signal generated from the timing controller 110. The data signal is supplied to a plurality of data lines provided in the liquid crystal panel 102. When the thin film transistor TFT is turned on due to the scan signal generated by the gate driver 104, the data signal is supplied to the plurality of data lines so that predetermined data is displayed on the liquid crystal panel 102.

The timing controller 110 generates a gate control signal for controlling the gate driver 104 by using a plurality of signals supplied from a system (not shown), and provides a data control signal for controlling the data driver 106. Create In addition, the timing controller 110 sorts and supplies the data supplied from the system to the data driver 106.

The backlight driver 112 may include an inverter 113 for generating a driving voltage for driving the backlight 108 and a failure detector 115 for detecting a failure by receiving a feedback of the driving voltage supplied to the backlight 108. It includes.                     

The inverter 113 generates a driving voltage for driving two lamps provided in the backlight 108 which are not shown. In other words, the driving voltage means an AC voltage for driving the plurality of lamps. The embodiment of the present invention takes the case of two lamps as an example.

The failure detection unit 115 receives and uses the feedback that the AC voltage generated by the inverter 113 is supplied to the backlight 108. That is, as illustrated in FIG. 4, the failure detector 115 detects a failure by using driving voltages supplied to the first and second lamps 101a and 101b provided in the backlight 108.

The failure detecting unit 115 may include a first sensor unit 114 and a second sensor unit 116 to which a driving voltage generated by the inverter 113 is supplied, and the first sensor unit 114 and a second sensor. An OR gate 117 to which signals generated by the unit 116 are supplied and a shut down controller 119 to which signals output according to logic logic are supplied to the OR gate 117.

When the driving voltage generated by the inverter 113 is supplied to the first lamp 101a through the electrode connection line 109, the first sensor unit 114 receives the driving voltage and generates a digital signal by using the feedback. do. That is, the first sensor unit 114 generates a digital signal of 0 when the driving voltage is supplied. When the driving voltage is supplied to the first sensor unit 114, the driving voltage generated by the inverter 113 is supplied to the first lamp 101a without opening the electrode connection line 109.

In addition, the first sensor unit 114 generates a digital signal of 1 when the driving voltage generated by the inverter 113 is not supplied. That is, the fact that the driving voltage is not supplied to the first sensor unit 114 means that the electrode connection line 109 is open, and the driving voltage generated by the inverter 113 to the first lamp 101a is It means no supply. The digital signal generated by the first sensor unit 114 is supplied to the OR gate 117.

When the driving voltage generated by the inverter 113 is supplied to the second lamp 101b through the electrode connection line 109, the second sensor unit 116 receives the driving voltage by using the feedback and receives the first voltage. Similar to the sensor unit 114 generates a digital signal. That is, the second sensor unit 116 generates a digital signal of 0 when the driving voltage is supplied. The driving voltage supplied to the second sensor unit 116 means that the driving voltage generated by the inverter 113 is supplied to the second lamp 101b without opening the electrode connection line 109.

In addition, the second sensor unit 116 generates a digital signal of 1 when the driving voltage generated by the inverter 113 is not supplied. That is, the fact that the driving voltage is not supplied to the second sensor unit 116 means that the electrode connection line 109 is open, and that the driving voltage generated by the inverter 113 by the second lamp 101b is It means no supply. The digital signal generated by the second sensor unit 116 is supplied to the OR gate 117.

The OR gate 117 generates a digital signal for controlling the shut down control unit 119 according to the logic of the digital signals supplied from the first and second sensor units 114 and 116. That is, as shown in FIG. 5, if the digital signal supplied from the first sensor unit 114 is 0 and the digital signal supplied from the second sensor unit 116 is 0, the OR gate 117 is zero. , Digital output 0.

The digital signal of 0 output from the OR gate 117 is supplied to the shut down controller 119. When the digital signal of 0 is input to the shut down controller 119, the shut down controller 119 prevents the shut down function from operating. That is, the shut down control unit 119 shuts down the inverter 113, that is, does not turn off.

When the digital signal output from the OR gate 117 is 0, the shut down controller 119 does not turn off the inverter 113, and the digital signal output from the OR gate 117 is 1. In this case, the inverter 113 is turned off to detect a failure caused by the electrode connection line 109 being turned off.

Accordingly, when the digital signal output from the OR gate 117 is 0, it means that the electrode connection line 109 connected to the first and second lamps 101a and 101b is not open. Therefore, the shut down control unit 119 does not turn off the inverter 113.

When the digital signal supplied from the first sensor unit 114 is 1 and the digital signal supplied from the second sensor unit 116 is 0, the OR gate 117 outputs a digital signal of 1. The digital signal of 1 output from the OR gate 117 is supplied to the shut down controller 119. When the digital signal of 1 is input to the shut down control unit 119, the shut down control unit 119 operates as a shut down function to turn off the inverter 113. Let's do it.

When the digital signal output from the OR gate 117 is 0, the shut down controller 119 does not turn off the inverter 113, and the digital signal output from the OR gate 117 is 1. In this case, the inverter 113 is turned off to detect a failure caused by the electrode connection line 109 being turned off. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b do not emit light. That is, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, the lamp driving device may detect that a failure has occurred.

Accordingly, when the digital signal output from the OR gate 117 is 1, it means that the electrode connection line 109 connected to the first and second lamps 101a and 101b is opened, thereby detecting a failure. Accordingly, the shut down control unit 119 turns off the inverter 113. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b do not emit light. That is, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, the lamp driving device may detect that a failure has occurred.

When the digital signal supplied from the first sensor unit 114 is 0 and the digital signal supplied from the second sensor unit 116 is 1, the OR gate 117 outputs a digital signal of 1. The digital signal of 1 output from the OR gate 117 is supplied to the shut down controller 119. When the digital signal of 1 is input to the shut down control unit 119, the shut down control unit 119 operates as a shut down function to operate the inverter 113. Turn it off. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b do not emit light. That is, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, the lamp driving device may detect that a failure has occurred.

When the digital signal output from the OR gate 117 is 0, the shut down controller 119 does not turn off the inverter 113, and the digital signal output from the OR gate 117 is 1. In this case, the inverter 113 is turned off to detect a failure caused by the electrode connection line 109 being turned off. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b do not emit light. That is, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, the lamp driving device may detect that a failure has occurred.

Thus, when the digital signal output from the OR gate 117 is 1, it means that the electrode connection line connected to the first and second lamps 101a and 101b is opened, thereby detecting a failure. Accordingly, the shut down control unit 119 turns off the inverter 113.

When the digital signal supplied from the first sensor unit 114 is 1 and the digital signal supplied from the second sensor unit 116 is 1, the OR gate 117 outputs a digital signal of 1. The digital signal of 1 output from the OR gate 117 is supplied to the shut down controller 119. When the digital signal of 1 is input to the shut down control unit 119, the shut down control unit 119 operates as a shut down function to turn off the inverter 113. Let's do it. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, a failure of the lamp driving device may be detected.

When the digital signal output from the OR gate 117 is 0, the shut down controller 119 does not turn off the inverter 113, and the digital signal output from the OR gate 117 is 1. In this case, the inverter 113 is turned off to detect a failure caused by the electrode connection line 109 being turned off.

As a result, when the digital signal output from the OR gate 117 is 1, it means that the electrode connection line connected to the first and second lamps 101a and 101b is opened, thereby detecting a defect in advance. Accordingly, the shut down control unit 119 turns off the inverter 113. Due to the inverter 113 being turned off, the first and second lamps 101a and 101b are not turned on. Due to the first and second lamps 101a and 101b not being turned on, a failure of the lamp driving device may be detected.

When the driving voltage generated by the inverter 113 is supplied to the first and second lamps 101a and 101b through the electrode connection line 109, the driving voltage is connected by connecting the electrode connection line 109 with a line. It is supplied to the first and second sensor unit 114, 116. The first and second sensor units 114 and 116 generate a digital signal using driving voltages supplied to the first and second sensor units 114 and 116. If the driving voltage is not supplied to the first and second sensor parts 114 and 116, the first and second sensor parts 114 and 116 generate a digital signal of 1, and the driving voltage is When supplied, the first and second sensor units 114 and 116 generate a digital signal of zero.

The OR gate 117 controls the shut down control unit 119 according to the logic of the digital signals generated by the first and second sensor units 114 and 116. When the digital signal output from the OR gate 117 is 0, the shut down control unit 119 does not turn off the inverter 113 and allows the inverter 113 to be driven normally. When the digital signal output from the OR gate 117 is 1, the shut down controller 119 turns off the inverter 113 and prevents the inverter 113 from being driven.

By providing the failure detecting unit 115, the inverter 113 is turned off and the first and second lamps 101a and 101b may not be turned on to detect a failure.

As mentioned above, the liquid crystal display according to the present invention includes a failure detecting unit that detects a failure by turning off the inverter when the electrode connection line is opened in the manufacturing process, so that the backlight driving voltage generated in the inverter is backlighted through the electrode connection line. When supplied to a plurality of lamps provided in, the failure caused by opening the electrode connecting line connected to one of the plurality of lamps can be detected by detecting that the plurality of lamps do not emit light.

 As described above, the lamp driving apparatus according to the present invention is supplied with a backlight driving voltage generated by an inverter to the backlight through an electrode connection line, by having a failure detecting unit for detecting the presence or absence of the electrode connection line in the process, When the electrode connection line is opened in the manufacturing process of the liquid crystal display device having the lamp driving device, the electrode connection line is sensed and the inverter is turned off to prevent the plurality of lamps from emitting light, thereby preventing leakage of the liquid crystal display device. have.

Claims (16)

A backlight having a plurality of lamps; An inverter generating a driving voltage to be supplied to the plurality of lamps; A plurality of connection lines branched between the inverter and the backlight to supply a driving voltage; And And a failure detection unit configured to sense driving voltages supplied to the plurality of lamps and control shutdown of the inverter according to a detection result. The method of claim 1, The failure detection unit, A plurality of sensor units sensing driving voltages supplied to the plurality of connection lines; An OR gate generating an output signal according to the plurality of driving voltages; And And a shut down controller controlling the inverter according to the output signal. The method of claim 2, Each of the sensor units outputs a signal of zero when the driving voltage is supplied. The method of claim 2, Each of the sensor units outputs a signal of 1 when the driving voltage is not supplied. The method of claim 2, And the OR gate outputs a signal of 1 when at least one signal is output from at least one of the plurality of sensor units. The method of claim 2, And the OR gate outputs a zero signal when all of the plurality of sensor units output a zero signal. The method of claim 2, The shut down control unit, And outputting a zero signal from the OR gate to maintain operation of the inverter. The method of claim 2, The shut down control unit, And a signal of 1 is output from the OR gate to shut down the operation of the inverter. A backlight having a plurality of lamps; An inverter generating a driving voltage supplied to the plurality of lamps; A failure detecting unit detecting a driving voltage supplied to the plurality of lamps branched between the inverter and the backlight and controlling shutdown of the inverter according to a detection result; And And a liquid crystal panel which displays an image according to the light emitted from the backlight. The method of claim 9, The failure detection unit, A plurality of sensor units sensing driving voltages supplied to the plurality of connection lines; An OR gate generating an output signal according to the plurality of driving voltages; And And a shut down controller controlling the inverter according to the output signal. The method of claim 10, And each of the sensor units outputs a signal of zero when the driving voltage is supplied. The method of claim 10, Each of the sensor units outputs a signal of 1 when the driving voltage is not supplied. The method of claim 10, And the OR gate outputs a signal of 1 when at least one signal is output from at least one of the plurality of sensor units. The method of claim 10, And the OR gate outputs a signal of zero when all of the plurality of sensor units output a signal of zero. The method of claim 10, The shut down control unit, And when a signal of 0 is output from the OR gate, maintaining the operation of the inverter. The method of claim 10, The shut down control unit, And when the signal of 1 is output from the OR gate, shuts down the operation of the inverter.

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