JP2014220155A - Light source device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect abnormal state of a light source more reliably without changing the conventional configuration as much as possible, in a light source device including a plurality of light sources.SOLUTION: A light source device 1 includes a light source circuit 20 in which a plurality of CCFLs 2 are connected in parallel, a control IC 5, and a protective circuit 6. When the voltage of an FB line 12 connected with the light source circuit 20 goes above an abnormality detection voltage value continuously for an abnormality detection time or more, the protective circuit 6 detects lamp cracking of the CCFL 2. When the current value of the FB line 12 goes below an abnormality detection current value, the control IC 5 increases the voltage between terminals of each CCFL 2. Consequently, the voltage of the FB line 12 increases above the abnormality detection voltage. The control IC 5 maintains the voltage of the FB line 12 above the abnormality detection voltage, the voltage being increased above the abnormality detection voltage.

Description

  The present invention relates to a light source device used as a backlight of a liquid crystal display, for example.

  Conventionally, for example, a light source device used as a backlight of a liquid crystal display includes a plurality of light sources (a plurality of light sources arranged in a planar shape). Moreover, in such a light source device, there is one using a CCFL (cold cathode tube lamp) as a light source. As such a light source device, one having the configuration shown in FIG. 2 is known.

  The light source device 70 illustrated in FIG. 2 includes a plurality of CCFLs 71, a T balance power supply circuit 72, a transformer 73, a control IC 74, and a protection circuit 75. The plurality of CCFLs 71 are connected in parallel between a G (Ground) line 81 and an FB (Feedback) line (abnormality detection line) 82.

  The T balance power supply circuit 72 generates a high frequency voltage under the control of the control IC 74, and outputs the generated high frequency voltage from the VBL + terminal 72a and the VBL− terminal 72b. The transformer 73 includes a plurality of primary side coils 73a and secondary side coils 73b (the same number as the CCFL 71). A plurality of (all) primary side coils 73 a of the transformer 73 are connected in series between the VBL + terminal 72 a and the VBL− terminal 72 b of the T balance power supply circuit 72. Each (one by one) secondary coil 73b of the transformer 73 is connected in series to each (one by one) CCFL 71. When the high frequency voltage is output from the T balance power supply circuit 72, the high frequency voltage is output from each secondary coil 73 b of the transformer 73, and the high frequency voltage is supplied between the terminals of each CCFL 71.

  The control IC 74 detects the current value of the FB line 82 based on the input from the Isen terminal 74a. The control IC 74 detects the output voltage value of the T balance power supply circuit 72 based on the input from the Vsen terminal 74b. The control IC 74 determines the T balance based on the current value of the FB line 82 detected based on the input from the Isen terminal 74a and the output voltage value of the T balance power supply circuit 72 detected based on the input from the Vsen terminal 74b. The output voltage of the power supply circuit 72 is controlled.

  When the voltage of the FB line 82 continues for a predetermined abnormality detection time or more and exceeds a predetermined abnormality detection voltage value, the protection circuit 75 detects that the CCFL 71 has a lamp crack (the CCFL 71 is in an abnormal state and at least one of the plurality of CCFLs 71). It is detected that one of the abnormal states is not lit). An abnormality detection time is set in order to prevent erroneous detection that the voltage of the FB line 82 temporarily exceeds the abnormality detection voltage value at the start of lighting of the CCFL 71 as a lamp crack of the CCFL 71.

  After the lighting of each CCFL 71, the control IC 74 has a current value of the FB line 82 that is less than a predetermined abnormality detection current value (a current value that is a predetermined current value smaller than the current value when all of the plurality of CCFLs 71 are lit). Then, the output voltage of the T balance power supply circuit 72 is increased. At this time, when the control IC 74 increases the output voltage of the T balance power supply circuit 72 and the current value of the FB line 82 reaches the overcurrent detection FB current value, the output of the T balance power supply circuit 72 is output. Reduce the voltage.

  In the light source device 70 having such a configuration, if any CCFL 71 breaks after the start of lighting of each CCFL 71, the current does not flow to the CCFL 71 that has broken the lamp, and the current value of the FB line 82 becomes less than the abnormal detection current value. . As a result, the output voltage of the T balance power supply circuit 72 is increased by the control IC 74, and the voltage across the terminals of the CCFL 71 increases. As a result, the voltage of the FB line 82 increases, and the voltage of the FB line 82 becomes equal to or higher than the abnormality detection voltage value. When the voltage of the FB line 82 continues for an abnormality detection time or more and becomes equal to or greater than the abnormality detection voltage value, the protection circuit 75 detects that the CCFL 71 is broken.

  On the other hand, when it is detected that a single cold cathode tube is provided and no current flows through the cold cathode tube, it is assumed that the cold cathode tube has become non-lighted due to a broken tube or the like, so that the operation of the cold cathode tube power supply circuit is stopped. A cold cathode tube non-lighting countermeasure circuit is known (see, for example, Patent Document 1). In addition, a leakage current sensor comprising a plurality of EEFL lamps and including a coil provided adjacent to each EEFL lamp detects the turn-off of each EEFL lamp, and the leakage current sensor turns off any EEFL lamp. A backlight unit that stops an inverter upon detection is known (see, for example, Patent Document 2).

Japanese Patent Laid-Open No. 10-134970 JP 2005-174909 A

  However, in the above-described conventional light source device 70, when the CCFL 71 is cracked, when the voltage between the terminals of the CCFL 71 rises, the voltage between the terminals of the CCFL 71 increases, so that the CCFL 71 that is broken is broken. May discharge from the chassis to the chassis. When discharge from the CCFL 71 having a broken lamp to the chassis occurs, the current of the FB line 82 increases, and the current value of the FB line 82 becomes equal to or higher than the overcurrent detection FB current value. As a result, the output voltage of the T balance power supply circuit 72 is lowered by the control IC 74, and the inter-terminal voltage of the CCFL 71 is lowered. As a result, the voltage of the FB line 82 decreases, and the voltage of the FB line 82 becomes less than the abnormality detection voltage value. Therefore, even if the CCFL 71 is broken, if the discharge from the terminal of the CCFL 71 where the lamp is broken occurs to the chassis before the abnormality detection time of the protection circuit 75 elapses, the voltage of the FB line 82 becomes abnormal. The abnormality does not exceed the abnormality detection voltage value continuously for the detection time or longer, and the protection circuit 75 does not detect that the CCFL 71 is broken.

  The present invention has been made to solve the above-described problems, and in a light source device including a plurality of light sources, a light source capable of more reliably detecting an abnormal state of the light source without changing the conventional configuration as much as possible. An object is to provide an apparatus.

  In order to achieve the above object, the light source device of the present invention has a light source circuit unit in which a plurality of light sources are connected in parallel, and a voltage of an abnormality detection line connected to the light source circuit unit continues for a predetermined abnormality detection time. When the abnormality detection voltage value is equal to or higher than the abnormality detection voltage value, the abnormality detection means for detecting that at least one of the plurality of light sources of the light source circuit unit is in an abnormal state and the current value of the current flowing through the abnormality detection line are the light source Voltage that increases the inter-terminal voltage of each light source in the light source circuit unit when the current value is less than a predetermined abnormality detection current value that is a predetermined current value smaller than the current value when all of the plurality of light sources in the circuit unit are lit A voltage maintaining means for maintaining the voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to the rise in the voltage between the terminals of each light source of the light source circuit unit by the voltage raising means, Obtain, is intended.

  According to this configuration, when the light source is in an abnormal state (an abnormal state in which at least one of the plurality of light sources of the light source circuit unit is not lit), the current value of the current flowing through the abnormality detection line is less than the abnormality detection current value. Thus, the voltage between the terminals of each light source is raised by the voltage raising means. When the voltage between the terminals of each light source increases, the voltage of the abnormality detection line increases. Then, the voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to the increase in the voltage between the terminals of each light source is maintained above the abnormality detection voltage value by the voltage maintaining means. As a result, when the light source is in an abnormal state, the voltage of the abnormality detection line is continuously maintained at the abnormality detection voltage value or more continuously for the abnormality detection time, and the abnormality detection unit detects that the light source is in an abnormal state. .

  Further, in the light source device of the present invention, the voltage maintaining means may be configured such that the voltage value between the terminals of the light source of the light source circuit unit when the discharge from the light source terminal of the light source circuit unit to the chassis may occur is the chassis discharge voltage value. It is desirable to limit the increase in the voltage between the terminals of each light source in the light source circuit unit by the voltage increasing means so that the voltage between the terminals of each light source in the light source circuit unit does not reach the chassis discharge voltage value.

  According to this configuration, the voltage maintaining means restricts the rise of the voltage between the terminals of each light source so that the voltage between the terminals of each light source does not reach the chassis discharge voltage value. The voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to the rise in the inter-terminal voltage is maintained above the abnormality detection voltage value.

  In the light source device of the present invention, the voltage maintaining means is a light source circuit by the voltage raising means so that the voltage between the terminals of each light source of the light source circuit section does not reach the chassis discharge voltage value based on the voltage of the abnormality detection line. It is desirable to limit an increase in the voltage between terminals of each light source of the unit.

  According to this configuration, the voltage maintaining means limits the increase in the voltage between the terminals of each light source so that the voltage between the terminals of each light source does not reach the chassis discharge voltage value based on the voltage of the abnormality detection line. Thus, the voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to the increase in the voltage between the terminals of each light source by the voltage raising means is maintained above the abnormality detection voltage value.

  Further, in the light source device of the present invention, the light source circuit section is formed by connecting a secondary coil of the transformer and the light source connected in series, and the voltage raising means is the secondary of the transformer of the light source circuit section. It is desirable to increase the voltage between the terminals of each light source in the light source circuit unit by increasing the output voltage of the side coil.

  According to this configuration, the output voltage of the secondary coil of the transformer is increased, so that the voltage between the terminals of each light source is increased.

  In the light source device of the present invention, it is preferable that the light source device further includes a protection unit that turns off each light source of the light source circuit unit when the abnormality detection unit detects an abnormal state.

  According to this configuration, when the light source is in an abnormal state, each light source is turned off.

  According to the present invention, when the light source is in an abnormal state (an abnormal state in which at least one of the plurality of light sources of the light source circuit unit is not lit), the voltage between the terminals of each light source is increased by the voltage increasing means. The voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to the increase in the voltage between the terminals of each light source is maintained above the abnormality detection voltage value by the voltage maintaining means. As a result, when the light source is in an abnormal state, the voltage of the abnormality detection line can be continuously maintained for the abnormality detection time or more and maintained at the abnormality detection voltage value or more. Accordingly, the abnormal state of the light source can be detected more reliably by the abnormality detection means. Moreover, the abnormal state of the light source can be detected more reliably without changing the conventional configuration as much as possible.

1 is an electric circuit diagram showing a schematic configuration of a light source device according to an embodiment of the present invention. The electric circuit diagram which shows the structure of the conventional light source device.

  Hereinafter, a light source device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows the configuration of the light source device according to the present embodiment. The light source device 1 is a device used as a backlight of a liquid crystal display, for example.

  The light source device 1 includes a light source circuit unit 20 in which a plurality of CCFLs (cold-cathode tube lamps) (light sources) 2 are connected in parallel, a T balance power supply circuit 3, a transformer 4, and a control IC (voltage raising means, voltage maintaining). Means) 5 and a protection circuit (abnormality detection means, protection means) 6.

  The light source circuit unit 20 is connected between a G (Ground) line 11 and an FB (Feedback) line (abnormality detection line) 12. That is, the plurality of CCFLs 2 of the light source circuit unit 20 are connected in parallel between the G line 11 and the FB line 12. The G line 11 has one end connected to the light source circuit unit 20 and the other end connected to the ground. The FB line 12 has one end connected to the light source circuit unit 20 and the other end connected to the protection circuit 6.

  CCFL2 is a lamp which is turned on when a high frequency voltage is supplied between the terminals, and starts lighting when the voltage between terminals (high frequency voltage supplied between the terminals) reaches a predetermined lighting start terminal voltage value. After the start of lighting, lighting is maintained at a predetermined lighting sustaining terminal voltage value whose terminal voltage is lower than the lighting start terminal voltage value.

  The transformer 4 and the T balance power supply circuit 3 are for generating a high frequency voltage (high frequency voltage for turning on the CCFL 2) supplied between the terminals of the CCFL 2. The transformer 4 and the T balance power supply circuit 3 constitute an inverter circuit that generates a high frequency voltage from a DC voltage.

  The T balance power supply circuit 3 generates a high frequency voltage from a DC voltage generated by a power supply circuit (not shown) under the control of the control IC 5, and outputs the generated high frequency voltage from the VBL + terminal 3a and the VBL− terminal 3b. .

  The transformer 4 includes a plurality of primary side coils 4a and secondary side coils 4b (the same number as the number of CCFLs 2). The plurality of (all) primary coils 4a of the transformer 4 are connected in series and connected between the VBL + terminal 3a and the VBL− terminal 3b of the T balance power supply circuit 3. In other words, the plurality of (all) primary coils 4 a of the transformer 4 are connected in series between the VBL + terminal 3 a and the VBL− terminal 3 b of the T balance power supply circuit 3.

  Each (one by one) secondary coil 4b of the transformer 4 is connected in series to each (one by one) CCFL2. Therefore, the light source circuit unit 20 has a configuration in which one secondary coil 4b of the transformer 4 and one CCFL 2 connected in series are connected in parallel. That is, a plurality of transformers 4 in which one secondary coil 4 b and one CCFL 2 are connected in series are connected in parallel between the G line 11 and the FB line 12. Each secondary coil 4 b is connected in series with CCFL 2 between CCFL 2 and FB line 12.

  The high-frequency voltage output from the T balance power supply circuit 3 is supplied to the primary side coil 4 a of the transformer 4. By outputting the high frequency voltage from the T balance power supply circuit 3, the high frequency voltage is output from each secondary coil 4b of the transformer 4, and the high frequency voltage is supplied between the terminals of each CCFL2. When the voltage value of the high frequency voltage output from the T balance power supply circuit 3 increases, the voltage value of the high frequency voltage output from each secondary coil 4b of the transformer 4 increases, and the high frequency voltage supplied between the terminals of each CCFL 2 increases. The voltage value of the voltage increases. Further, when the voltage value of the high-frequency voltage output from the T balance power supply circuit 3 decreases, the voltage value of the high-frequency voltage output from each secondary coil 4b of the transformer 4 decreases and is supplied between the terminals of each CCFL2. The voltage value of the high frequency voltage decreases. The sum of the currents flowing through the secondary coils 4b of the transformer 4 (currents flowing between the terminals of the CCFLs 2) is the current flowing through the FB line 12.

  The control IC 5 controls lighting of the CCFL 2. That is, the control IC 5 controls the output start and output stop of the voltage (high frequency voltage) from the T balance power supply circuit 3, and also controls the output voltage (the magnitude of the high frequency voltage to be output) of the T balance power supply circuit 3. Is. The control IC 5 operates when a DC voltage generated by a power supply circuit (not shown) is supplied.

  The control IC 5 has an Isen terminal 5a, and the Isen terminal 5a is connected to the FB line 12 via resistors 31 and 32. The Isen terminal 5a and the resistor 31 are connected to the ground via a resistor 33. The control IC 5 detects the current value of the FB line 12 based on the input from the Isen terminal 5a.

  The control IC 5 has a Vsen terminal 5b, and the Vsen terminal 5b is connected to the FB line 12 through a diode 34. The diode 34 has an anode connected to the FB line 12 and a cathode connected to the Vsen terminal 5b. The control IC 5 detects the voltage value of the FB line 12 based on the input from the Vsen terminal 5b.

  The control IC 5 detects the current value of the FB line 12 detected based on the input from the Isen terminal 5a and the voltage value of the FB line 12 detected based on the input from the Vsen terminal 5b. To control the output voltage.

  The protection circuit 6 detects a CCFL2 lamp break (an abnormal state of the CCFL 2 and at least one of the plurality of CCFLs 2 is not lit), and detects a CCFL 2 lamp break. Each CCFL 2 is turned off. The protection circuit 6 detects the CCFL2 lamp breakage based on the voltage of the FB line 12 connected to the light source circuit unit 20. Then, when the protection circuit 6 detects the lamp breakage of the CCFL 2, it turns off the power source of the light source device 1 (stops the generation of a DC voltage by a power circuit (not shown) and stops the operation of the light source device 1). Each CCFL2 is turned off. The protection circuit 6 constitutes an abnormality detection unit and a protection unit.

  When the voltage of the FB line 12 continues for a predetermined lamp crack detection time (abnormal detection time) or more than a predetermined lamp crack detection FB voltage value (abnormal detection voltage value), the protection circuit 6 Detect that there is. The lamp crack detection FB voltage value is a voltage value for detecting CCFL2 lamp cracking. When the CCFL2 lamp cracking does not occur, all CCFL2s maintain lighting at the lighting sustaining terminal voltage value. The voltage value is higher than the voltage value of the FB line 12 by a predetermined voltage value. The lamp crack detection FB voltage value is obtained and set in advance by a test or the like. The lamp crack detection time is a time period for preventing erroneous detection that the voltage of the FB line 12 temporarily exceeds the lamp crack detection FB voltage value at the start of lighting of the CCFL2 as a lamp crack of the CCFL2. , Approximately the time required to start the lighting of CCFL2. The lamp crack detection time is obtained and set in advance by a test or the like.

  When the power source of the light source device 1 is turned on, the control IC 5 outputs a voltage from the T balance power supply circuit 3 and lights the CCFL 2. When the control IC 5 receives an instruction to turn off the CCFL 2 while the CCFL 2 is turned on, the control IC 5 stops the output of the voltage from the T balance power supply circuit 3 and turns off the CCFL 2. Further, the control IC 5 gives an instruction to turn on the CCFL 2 when the power source of the light source device 1 is turned on and the CCFL 2 is turned off (when the voltage output from the T balance power supply circuit 3 is stopped). When received, a voltage is output from the T balance power supply circuit 3 to light the CCFL 2.

  When the control IC 5 turns on the CCFL 2, it first performs a starting operation, and then performs a normal operation after performing the starting operation. The start-up operation is an operation for controlling the output voltage of the T balance power supply circuit 3 in order to start lighting of the CCFL 2. In normal operation, the output voltage of the T balance power supply circuit 3 is controlled in order to maintain the lighting of the CCFL 2, and the output voltage of the T balance power supply circuit 3 is controlled in order to make the protection circuit 6 detect the lamp breakage of the CCFL 2. Is the action.

  The control IC 5 controls the output voltage of the T balance power supply circuit 3 as a startup operation as follows.

  When the control IC 5 turns on the CCFL 2, it first starts outputting the voltage from the T balance power supply circuit 3 and then increases the output voltage of the T balance power supply circuit 3. When the output voltage of the T balance power supply circuit 3 rises, the output voltage of each secondary coil 4b of the transformer 4 rises, and the voltage between the terminals of each CCFL 2 rises. That is, when turning on the CCFL 2, the control IC 5 first increases the output voltage of each secondary coil 4b of the transformer 4 by increasing the output voltage of the T balance power supply circuit 3, The voltage between terminals of CCFL2 is increased.

  Subsequently, the control IC 5 increases the voltage between the terminals of each CCFL 2 (in the process of increasing the output voltage of the T balance power supply circuit 3), based on the input from the Isen terminal 5a, The current is detected, and it is determined whether or not the current of the FB line 12 has reached a predetermined full lighting start FB current value. The all lighting start FB current value is a current value for determining that all CCFLs 2 have started lighting. The total lighting start FB current value is obtained and set in advance by a test or the like.

  In the process of increasing the inter-terminal voltage of each CCFL 2, when the current of the FB line 12 reaches the full lighting start FB current value, all the CCFLs 2 start lighting at the lighting start inter-terminal voltage value. The increase of the output voltage of the T balance power supply circuit 3 is stopped. Then, the control IC 5 reduces the output voltage of the T balance power supply circuit 3 from the output voltage at that time. When the output voltage of the T balance power supply circuit 3 decreases, the output voltage of each secondary coil 4b of the transformer 4 decreases, and the voltage between the terminals of each CCFL 2 decreases. That is, the control IC 5 decreases the output voltage of the T balance power supply circuit 3 when the current of the FB line 12 reaches the full lighting start FB current value in the process of increasing the voltage between the terminals of each CCFL 2. As a result, the output voltage of each secondary coil 4b of the transformer 4 is lowered, and the voltage between the terminals of each CCFL 2 is lowered.

  Subsequently, the control IC 5 reduces the voltage between the terminals of each CCFL 2 (in the process of decreasing the output voltage of the T balance power supply circuit 3), based on the input from the Isen terminal 5a. The current is detected, and it is determined whether or not the current value of the FB line 12 has decreased to a predetermined full lighting maintenance FB current value. The total lighting maintenance FB current value is the current value of the FB line 12 when all of the plurality of CCFLs 2 are maintained at the lighting maintenance terminal voltage value when the CCFL 2 is not broken, that is, CCFL 2 This is the current value of the FB line 12 when the voltage between the terminals of each CCFL 2 becomes the voltage value between the lighting sustaining terminals when the lamp crack does not occur. The total lighting maintenance FB current value is obtained and set in advance by a test or the like.

  In the process of decreasing the voltage between the terminals of each CCFL 2, when the current of the FB line 12 decreases to the full lighting maintenance FB current value, the control IC 5 maintains all the CCFLs 2 at the lighting maintenance terminal voltage value. Therefore, it is determined that the output voltage of the T balance power supply circuit 3 is lowered. Then, the control IC 5 maintains the output voltage of the T balance power supply circuit 3 at the output voltage at that time (when the current of the FB line 12 is the full lighting maintenance FB current value). As a result, the current of the FB line 12 is maintained at the full lighting maintenance FB current value (if the CCFL2 is not broken, the voltage between the terminals of each CCFL2 is maintained at the lighting maintenance terminal voltage value). That is, the control IC 5 reduces the output voltage of the T balance power supply circuit 3 at that time when the current of the FB line 12 decreases to the full lighting maintenance FB current value in the process of decreasing the voltage between the terminals of each CCFL 2. Thus, the current of the FB line 12 is maintained at the full lighting maintenance FB current value. The control IC 5 controls the output voltage of the T balance power supply circuit 3 as described above as the starting operation.

  The lamp crack detection FB voltage value in the protection circuit 6 is higher by a predetermined voltage value than the voltage value of the FB line 12 when the current of the FB line 12 is the full lighting maintenance FB current value (however, the current of the FB line 12 is all The voltage value is set to be lower than the voltage value of the FB line 12 at the lighting start FB current value.

  Also, the lamp crack detection time in the protection circuit 6 is determined so that the output voltage of the T balance power supply circuit 3 is equal to the current of the FB line 12 after the output of the voltage from the T balance power supply circuit 3 is started in the starting operation of the control IC 5. The time is set to about the time until the output voltage is maintained at the full lighting maintenance FB current value.

  The control IC 5 controls the output voltage of the T balance power supply circuit 3 as follows as a normal operation.

  After performing the starting operation, the control IC 5 detects the current of the FB line 12 based on the input from the Isen terminal 5a, and the current value of the FB line 12 is a predetermined non-lighting detection FB current value (abnormal detection current value). ) Determine whether it is above. The non-lighting detection FB current value is a current value for determining that at least one of all the CCFLs 2 is not lit, and the all lighting maintaining FB current value (CCFL2 is not broken). Sometimes the current value is smaller than the current value of the FB line 12 when all of the plurality of CCFLs 2 are kept lit at the voltage value between the lighting maintenance terminals. The non-lighting detection FB current value is obtained and set in advance by a test or the like.

  When the current value of the FB line 12 is not less than the non-lighting detection FB current value, the control IC 5 keeps the output voltage of the T balance power supply circuit 3 constant (in the start-up operation, the current of the FB line 12 is fully lit). The output voltage of the T balance power supply circuit 3 is controlled so that the output voltage is maintained at the maintenance FB current value. That is, when the current value of the FB line 12 is not less than the non-lighting detection FB current value, the control IC 5 detects the voltage of the FB line 12 based on the input from the Vsen terminal 5b, and the FB line 12 The output voltage of the T balance power supply circuit 3 is controlled so as to keep the voltage at a constant (the voltage when the current of the FB line 12 is maintained at the full lighting maintenance FB current value in the starting operation). As a result, the current of the FB line 12 is maintained at the full lighting maintenance FB current value (if the CCFL2 is not broken, the voltage between the terminals of each CCFL2 is maintained at the lighting maintenance terminal voltage value).

  That is, after the start-up operation, the control IC 5 keeps the output voltage of the T balance power supply circuit 3 constant when the current value of the FB line 12 is not less than the non-lighting detection FB current value (of the FB line 12). By controlling the output voltage of the T balance power supply circuit 3 so that the voltage of the FB line 12 is kept constant based on the voltage), the current of the FB line 12 is maintained at the full lighting maintenance FB current value.

  On the other hand, when the current value of the FB line 12 becomes less than the non-lighting detection FB current value, the control IC 5 controls the output voltage of the T balance power supply circuit 3 as follows.

  When the current value of the FB line 12 becomes less than the non-lighting detection FB current value, the control IC 5 first increases the output voltage of the T balance power supply circuit 3. When the output voltage of the T balance power supply circuit 3 rises, the output voltage of each secondary coil 4b of the transformer 4 rises, and the voltage between the terminals of each CCFL 2 rises. That is, when the current value of the FB line 12 becomes less than the non-lighting detection FB current value, the control IC 5 first increases the output voltage of the T balance power supply circuit 3 to thereby each secondary coil 4b of the transformer 4. The output voltage of the CCFL2 is increased and the voltage between the terminals of each CCFL2 is increased. The control IC 5 constitutes voltage raising means.

  At this time, the control IC 5 increases the voltage between the terminals of each CCFL 2 (in the process of increasing the output voltage of the T balance power supply circuit 3), based on the input from the Isen terminal 5a, The current is detected, and it is determined whether or not the current of the FB line 12 has reached a predetermined overcurrent detection FB current value or more. The overcurrent detection FB current value is a current value for detecting that the current flows abnormally excessively, and is set to a current value higher than the full lighting start FB current value. The overcurrent detection FB current value is obtained and set in advance by a test or the like.

  The control IC 5 increases the output voltage of the T balance power supply circuit 3 when the current of the FB line 12 reaches the overcurrent detection FB current value in the process of increasing the voltage between the terminals of each CCFL 2. To stop. Then, the control IC 5 reduces the output voltage of the T balance power supply circuit 3 from the output voltage at that time. When the output voltage of the T balance power supply circuit 3 decreases, the output voltage of each secondary coil 4b of the transformer 4 decreases, and the voltage between the terminals of each CCFL 2 decreases. That is, the control IC 5 reduces the output voltage of the T balance power supply circuit 3 when the current value of the FB line 12 reaches the overcurrent detection FB current value in the process of increasing the voltage between the terminals of each CCFL 2. By doing so, the output voltage of each secondary coil 4b of the transformer 4 is lowered, and the voltage between the terminals of each CCFL 2 is lowered.

  Further, the control IC 5 detects the voltage of the FB line 12 based on the input from the Vsen terminal 5b in the process of increasing the voltage between the terminals of each CCFL 2, and the voltage of the FB line 12 is detected to be a predetermined upper limit detection FB. It is determined whether or not the voltage value has been reached. The upper limit detection FB voltage value is a voltage value for determining that the inter-terminal voltage of the CCFL 2 has reached the upper limit. From the voltage value of the FB line 12 when the current of the FB line 12 is the full lighting start FB current value Is set to a higher voltage value (thus, a voltage value higher than the lamp breakage detection FB voltage value). The upper limit detection FB voltage value is set so that the current of the FB line 12 is less than the overcurrent detection FB current value when the voltage of the FB line 12 is the upper limit detection FB voltage value. Further, the upper limit detection FB voltage value is the upper limit of the voltage of the FB line 12 when the voltage value of the terminal voltage of the CCFL 2 when the discharge from the terminal of the CCFL 2 having a broken lamp can occur to the chassis is the chassis discharge voltage value. When the detected FB voltage value, the inter-terminal voltage of the CCFL 2 is set to be less than the chassis discharge voltage value (the voltage value at which no discharge from the CCFL 2 terminal where the lamp is cracked occurs to the chassis). The upper limit detection FB voltage value is obtained and set in advance by a test or the like.

  The control IC 5 increases the output voltage of the T balance power supply circuit 3 when the voltage of the FB line 12 reaches the upper limit detection FB voltage value in the process of increasing the voltage between the terminals of each CCFL 2. Stop. When the voltage of the FB line 12 is the upper limit detection FB voltage value, since the current of the FB line 12 is less than the overcurrent detection FB current value, before the current of the FB line 12 reaches the overcurrent detection FB current value, the FB line 12 The voltage of 12 reaches the upper limit detection FB voltage value, and the increase of the output voltage of the T balance power supply circuit 3 is stopped. Then, the control IC 5 maintains the output voltage of the T balance power supply circuit 3 at the output voltage at that time (when the voltage of the FB line 12 is the upper limit detection FB voltage value). When the voltage of the FB line 12 is the upper limit detection FB voltage value, the inter-terminal voltage of the CCFL 2 is less than the chassis discharge voltage value. That is, when the voltage of the FB line 12 reaches the upper limit detection FB voltage value in the process of increasing the voltage between the terminals of each CCFL 2, the control IC 5 outputs the output voltage of the T balance power supply circuit 3 at that time (FB line 12 Is maintained at the output voltage of the upper limit detection FB voltage value), the inter-terminal voltage of CCFL2 is maintained below the chassis discharge voltage value. That is, the control IC 5 increases the terminal voltage of each CCFL 2 so that the terminal voltage of each CCFL 2 does not reach the chassis discharge voltage value based on the voltage of the FB line 12 in the process of increasing the terminal voltage of each CCFL 2. Limit the voltage rise between the two. At this time, the voltage of the FB line 12 rises above the lamp crack detection FB voltage value at a certain point in time until reaching the upper limit detection FB voltage value.

  Since the output voltage of the T balance power supply circuit 3 is maintained at the output voltage at that time (when the voltage value of the FB line 12 is the upper limit detection FB voltage value), thereafter (the voltage of the FB line 12 becomes the upper limit detection FB voltage value). After that, the current of the FB line 12 does not increase due to the increase of the output voltage of the T balance power supply circuit 3. Further, since the inter-terminal voltage of CCFL2 is maintained below the chassis discharge voltage value, after that (after the voltage of the FB line 12 reaches the upper limit detection FB voltage value), the CCFL2 terminal that has broken the lamp is connected to the chassis. The discharge does not occur, and the current in the FB line 12 does not increase due to the discharge from the terminal of the CCFL2 where the lamp is cracked to the chassis. Therefore, the current of the FB line 12 does not increase from the current when the voltage of the FB line 12 is the upper limit detection FB voltage value, and does not reach the overcurrent detection FB current value. Since the current of the FB line 12 does not reach the overcurrent detection FB current value, the control IC 5 does not decrease the output voltage of the T balance power supply circuit 3, and the output voltage of the T balance power supply circuit 3 is not reduced. (When the voltage of the FB line 12 is the upper limit detection FB voltage value), the output voltage is maintained. As a result, the voltage of the FB line 12 is maintained at the upper limit detection FB voltage value, and is maintained above the lamp crack detection FB voltage value.

  That is, the control IC 5 maintains the output voltage of the T balance power supply circuit 3 at the output voltage when the voltage of the FB line 12 is the upper limit detection FB voltage value, and maintains the inter-terminal voltage of the CCFL 2 below the chassis discharge voltage value. By restricting the rise of the voltage between terminals of each CCFL 2 so that the voltage between the terminals of each CCFL 2 does not reach the chassis discharge voltage value, the voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value is The lamp breakage detection FB voltage value is maintained above the value. The control IC 5 constitutes voltage maintaining means.

  As described above, after the start-up operation, the control IC 5 controls the output voltage of the T balance power supply circuit 3 when the current value of the FB line 12 becomes less than the non-lighting detection FB current value. And the voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value is maintained above the lamp crack detection FB voltage value. As a normal operation, the control IC 5 controls the output voltage of the T balance power supply circuit 3 as described above.

  When the light source device 1 starts lighting the CCFL 2 (when the power source of the light source device 1 is turned on or when the power source of the light source device 1 is turned on and the CCFL 2 is turned off, an instruction to turn on the CCFL 2 is given. ), The following operation is performed (assuming that the CCFL2 is not cracked).

  First, the output voltage of the T-balance power supply circuit 3 is raised by the control IC 5, whereby the output voltage of each secondary coil 4 b of the transformer 4 is raised, and the voltage between the terminals of each CCFL 2 is increased. It will be raised. Thereby, the voltage between terminals of each CCFL2 rises and reaches the voltage value between lighting start terminals.

  When the inter-terminal voltage of each CCFL 2 reaches the lighting start inter-terminal voltage value, each CCFL 2 starts to light (current begins to flow through each CCFL 2), and the current flowing through each CCFL 2 increases. At this time, the current flowing through each CCFL2 increases as the inter-terminal resistance of the CCFL2 decreases due to the increase in the current flowing through the CCFL2, and increases as the inter-terminal voltage of the CCFL2 increases. . As the current flowing through each CCFL 2 increases, the current of the FB line 12 increases and the voltage of the FB line 12 increases. Thereby, the current of the FB line 12 increases and reaches the full lighting start FB current value. In addition, the voltage of the FB line 12 becomes equal to or higher than the lamp crack detection FB voltage value at a certain time until the current of the FB line 12 reaches the full lighting start FB current value.

  When the current value of the FB line 12 reaches the full lighting start FB current value, the control IC 5 determines that all the CCFLs 2 have started lighting, and the output voltage of the T balance power supply circuit 3 is lowered. The output voltage of each secondary coil 4b of the transformer 4 is lowered, and the voltage between the terminals of each CCFL 2 is lowered. As the voltage between the terminals of each CCFL2 decreases, the current flowing through each CCFL2 decreases. As the current flowing through each CCFL 2 decreases, the current of the FB line 12 decreases and the voltage of the FB line 12 decreases. As a result, the current of the FB line 12 decreases and becomes the full lighting maintenance FB current value. In addition, the voltage of the FB line 12 becomes lower than the lamp crack detection FB voltage value at a certain point in time until the current of the FB line 12 decreases to the full lighting maintenance FB current value.

  At this time, the voltage of the FB line 12 becomes equal to or higher than the lamp crack detection FB voltage value at a certain time until the current of the FB line 12 reaches the full lighting start FB current value, and before the lamp crack detection time elapses. The lamp breakage detection FB voltage value becomes lower. Therefore, the voltage of the FB line 12 does not continuously exceed the lamp crack detection FB voltage value for the lamp crack detection time or more, and the protection circuit 6 does not erroneously detect CCFL2 lamp crack.

  When the current value of the FB line 12 decreases to the full lighting maintenance FB current value, the output voltage of the T balance power supply circuit 3 is that time (when the current value of the FB line 12 is the full lighting maintenance FB current value) by the control IC 5. By maintaining the output voltage, the current of the FB line 12 is maintained at the full lighting maintenance FB current value, and the terminal voltage of each CCFL 2 is maintained at the lighting maintenance terminal voltage value. Thereby, each CCFL2 maintains lighting with the voltage value between lighting maintaining terminals. The light source device 1 operates in this way when starting the lighting of the CCFL 2, and each CCFL 2 starts to light.

  The light source device 1 operates as follows after the CCFL 2 starts to be lit (when the CCFL 2 is kept lit) and the CCFL 2 is not broken.

  After CCFL2 starts lighting, if the CCFL2 is not broken, the voltage between the terminals of each CCFL2 is maintained at the voltage value between the lighting sustaining terminals, and each CCFL2 is the voltage value between the lighting sustaining terminals. Keep on. As a result, each CCFL 2 is supplied with a current when the lighting is maintained at the lighting sustaining terminal voltage value, and the current of the FB line 12 becomes the full lighting maintaining FB current value (more than the non-lighting detection FB current value). Become.

  Since the current of the FB line 12 is equal to or greater than the non-lighting detection FB current value, the control IC 5 maintains the output voltage of the T balance power supply circuit 3 constant, so that the current of the FB line 12 is constant (all lighting maintenance FB current The voltage between the terminals of each CCFL 2 is kept constant (at the voltage value between the lighting maintaining terminals). Thereby, each CCFL2 maintains lighting with the voltage value between lighting maintaining terminals. The light source device 1 operates in this way when the CCFL 2 has not been cracked after the CCFL 2 starts lighting, and each CCFL 2 maintains lighting.

  The light source device 1 operates as follows when the CCFL2 starts to be lit (when the CCFL2 is kept lit) and the CCFL2 is broken.

  When CCFL2 starts to light after CCFL2 starts lighting, current stops flowing to CCFL2 where the lamp is cracked, and the current of FB line 12 decreases from the full lighting maintenance FB current value, and the non-lighting detection FB current value. Less than.

  When the current value of the FB line 12 becomes less than the non-lighting detection FB current value, the output voltage of the T-balance power supply circuit 3 is raised by the control IC 5, thereby the output voltage of each secondary coil 4 b of the transformer 4. Is increased, and the voltage between the terminals of each CCFL 2 is increased. As the inter-terminal voltage of each CCFL 2 increases, the current flowing between the terminals of each CCFL 2 increases. As the current flowing through each CCFL 2 increases, the current of the FB line 12 increases and the voltage of the FB line 12 increases. Thereby, the voltage of the FB line 12 rises and reaches the upper limit detection FB voltage value. The voltage of the FB line 12 rises above the lamp crack detection FB voltage value at a certain point in time until the upper limit detection FB voltage value is reached. When the voltage of the FB line 12 is the upper limit detection FB voltage value, the current of the FB line 12 is less than the overcurrent detection FB current value, and the terminal voltage of each CCFL 2 is less than the chassis discharge voltage value. Therefore, before the current of the FB line 12 reaches the overcurrent detection FB current value, and the discharge from the terminal of the CCFL2 where the lamp is broken does not occur to the chassis, the voltage of the FB line 12 becomes the upper limit detection FB voltage. Reach value.

  When the voltage value of the FB line 12 reaches the upper limit detection FB voltage value, the output voltage of the T balance power supply circuit 3 at that time (when the voltage value of the FB line 12 is the upper limit detection FB voltage value) is controlled by the control IC 5. Thus, the voltage value of the FB line 12 is maintained at the upper limit detection FB voltage value, and the voltage between the terminals of each CCFL 2 is maintained below the chassis discharge voltage value. That is, the control IC 5 maintains the voltage value of the FB line 12 at the upper limit detection FB voltage value based on the voltage of the FB line 12, and also prevents the terminal voltage of each CCFL2 from reaching the chassis discharge voltage value. The rise in the voltage between terminals of each CCFL 2 is limited.

  By maintaining the output voltage of the T balance power supply circuit 3 at that time (when the voltage value of the FB line 12 is the upper limit detection FB voltage value), the output voltage of the T balance power supply circuit 3 is increased thereafter. The current of the FB line 12 does not increase. In addition, since the inter-terminal voltage of CCFL2 is maintained below the chassis discharge voltage value, there is no subsequent discharge from the terminal of CCFL2 that has undergone lamp cracking to the chassis, and the terminal of CCFL2 that has undergone lamp cracking. The current in the FB line 12 does not increase due to the discharge from the chassis to the chassis. Therefore, the current of the FB line 12 does not increase thereafter and does not reach the overcurrent detection FB current value.

  Since the current of the FB line 12 does not reach the overcurrent detection FB current value, the output voltage of the T balance power supply circuit 3 is not lowered by the control IC 5. Therefore, the output voltage of the T balance power supply circuit 3 continues to be maintained at the output voltage when the voltage value of the FB line 12 is the upper limit detection FB voltage value, and the voltage value of the FB line 12 is maintained at the upper limit detection FB voltage value. to continue. As a result, the voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value continues to be maintained above the lamp crack detection FB voltage value.

  After the voltage of the FB line 12 becomes equal to or higher than the lamp crack detection FB voltage value at a certain time until reaching the upper limit detection FB voltage value, the lamp crack detection is continued without becoming less than the lamp crack detection FB voltage value. It is maintained above the FB voltage value. Thereby, the voltage of the FB line 12 continues for the lamp crack detection time or longer and becomes equal to or higher than the lamp crack detection FB voltage value.

  Thereby, it is detected by the protection circuit 6 that the lamp is cracked in CCFL2. Then, the power source of the light source device 1 is turned off by the protection circuit 6 (the generation of a DC voltage by a power circuit (not shown) is stopped and the operation of the light source device 1 is stopped), and each CCFL 2 is turned off. The light source device 1 operates in this way when the CCFL2 lamp breaks after the CCFL2 starts lighting, detects the CCFL2 lamp breakage, the light source device 1 is turned off, and each CCFL2 Turns off.

  As described above, according to the light source device 1 configured as described above, when the CCFL2 is broken, the control IC 5 increases the voltage between the terminals of each CCFL2, and the increase in the voltage between the terminals of each CCFL2. The voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value is maintained by the control IC 5 above the lamp crack detection FB voltage value. Thereby, when the CCFL2 lamp breakage occurs, the voltage of the FB line 12 can be maintained at the lamp breakage detection FB voltage value or more continuously for the lamp breakage detection time or longer. Therefore, the protection circuit 6 can detect the lamp crack of the CCFL 2 more reliably.

  Moreover, the control IC 5 is configured to maintain the voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value due to the increase in the inter-terminal voltage of each CCFL 2 above the lamp crack detection FB voltage value. With such a configuration, it is possible to more reliably detect a lamp crack of the CCFL 2 without changing the conventional configuration as much as possible. That is, it is possible to detect the CCFL2 lamp crack more reliably without a large cost increase.

  Further, the control IC 5 restricts the rise of the inter-terminal voltage of each CCFL 2 so that the inter-terminal voltage of each CCFL 2 does not reach the chassis discharge voltage value, so that the lamp crack detection FB is caused by the rise of the inter-terminal voltage of each CCFL 2. The voltage of the FB line 12 that has risen above the voltage value is maintained at the lamp break detection FB voltage value or higher. With such a configuration, it is possible to more reliably detect the lamp crack of the CCFL 2 without further changing the conventional configuration.

  Further, the control IC 5 restricts the rise of the inter-terminal voltage of each CCFL 2 based on the voltage of the FB line 12 so that the inter-terminal voltage of each CCFL 2 does not reach the chassis discharge voltage value. The voltage of the FB line 12 that has risen above the lamp crack detection FB voltage value due to the rise of the inter-voltage is maintained at or above the lamp crack detection FB voltage value. With such a configuration, it is possible to more reliably detect the lamp crack of the CCFL 2 without further changing the conventional configuration.

  In addition, this invention is not restricted to the structure of the said embodiment, A various deformation | transformation is possible. For example, instead of detecting the voltage of the FB line, the control IC detects the output voltage of the T balance power supply circuit, and in normal operation, each CCFL is based on the output voltage of the T balance power supply circuit. The increase in the output voltage of the T balance power supply circuit may be limited (the increase in the voltage between the terminals of each CCFL) may be restricted so that the terminal voltage does not reach the chassis discharge voltage value. Even with such a configuration, the voltage of the FB line can be maintained at the lamp crack detection FB voltage value or more continuously for the lamp crack detection time or more, and the CCFL lamp crack can be detected more reliably.

  Further, the control IC limits the increase in the output voltage of the T balance power supply circuit so that the inter-terminal voltage of each CCFL does not reach the chassis discharge voltage value in normal operation (limits the increase in the inter-terminal voltage of each CCFL). In addition, the output voltage of the T balance power supply circuit may not be reduced when the current of the FB line becomes equal to or greater than the overcurrent detection FB current value. According to such a configuration, even if discharge occurs from the terminal of the CCFL whose lamp is cracked to the chassis, the output voltage of the T balance power supply circuit does not decrease, and the voltage of the FB line does not decrease. Therefore, even with such a configuration, the voltage of the FB line can be maintained for the lamp crack detection FB voltage value continuously for the lamp crack detection time or more, and the lamp crack of the CCFL can be detected more reliably.

  Further, when the protection circuit detects a lamp breakage of the CCFL, the voltage from the T balance power supply circuit is maintained without turning off the power supply of the light source device (while maintaining the power supply state of the light source device). Each CCFL may be extinguished by stopping the output.

1 Light source device 2 CCFL (light source)
3 T Balance Power Supply Circuit 3a VBL + Terminal 3b VBL- Terminal 4 Transformer 4a Primary Coil 4a
4b Secondary coil 4b
5 Control IC (Voltage increasing means, voltage maintaining means)
5a Isen terminal 5b Vsen terminal 6 Protection circuit (abnormality detection means, protection means)
11 G line 12 FB line (abnormality detection line)
20 Light source circuit 31, 32, 33 Resistor 34 Diode

Claims (5)

A light source circuit unit in which a plurality of light sources are connected in parallel;
When the voltage of the abnormality detection line connected to the light source circuit unit continues for a predetermined abnormality detection time or more and exceeds a predetermined abnormality detection voltage value, at least one of the plurality of light sources of the light source circuit unit is not lit. An abnormality detection means for detecting an abnormal state;
When the current value of the current flowing through the abnormality detection line is less than a predetermined abnormality detection current value that is a predetermined current value smaller than a current value when all of the plurality of light sources of the light source circuit unit are lit, Voltage increasing means for increasing the voltage between terminals of each light source in the circuit section;
Voltage maintaining means for maintaining the voltage of the abnormality detection line that has risen above the abnormality detection voltage value due to an increase in the voltage between the terminals of each light source of the light source circuit unit by the voltage raising means;
A light source device comprising: The voltage maintaining means is
When the voltage value between the terminals of the light source of the light source circuit unit when the discharge from the light source terminal of the light source circuit unit to the chassis can occur is the chassis discharge voltage value,
Limiting the voltage increase between terminals of each light source of the light source circuit unit by the voltage increasing means so that the voltage between terminals of each light source of the light source circuit unit does not reach the chassis discharge voltage value,
The light source device according to claim 1. The voltage maintaining means is based on the voltage of the abnormality detection line so that the voltage between terminals of each light source of the light source circuit section does not reach the chassis discharge voltage value. Limit the rise of the voltage between the terminals of the light source,
The light source device according to claim 2. In the light source circuit unit, a secondary side coil of a transformer and a light source connected in series are connected in parallel.
The voltage increasing means increases a voltage between terminals of each light source of the light source circuit unit by increasing an output voltage of a secondary side coil of the transformer of the light source circuit unit.
The light source device according to claim 1, wherein the light source device is a light source device. When the abnormality detection unit detects that the abnormal state is detected, the apparatus further includes a protection unit that turns off each light source of the light source circuit unit.
The light source device according to claim 1, wherein the light source device is a light source device.

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