JP2006351450A - Circuit for detecting lamp open-circuit state in lamp lighting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a circuit for detecting lamp open-circuit state, suitable for miniaturization and cost reduction, which will not cause deterioration of lamp driving efficiency. <P>SOLUTION: In the lamp lighting device, on-off control of semiconductor switching devices Q1 to Q4 is carried out, a high-frequency signal is generated and it is supplied to the primary sides of output transformers T71 to T74, lighting apparatuses L1 to L16 are lighted which are connected to the secondary sides of the output transformers, lamp current flowing in the lighting apparatuses L1 to L16 is detected, PWM (Pulse Width Modulation) control of the semiconductor switching devices Q1 to Q4, based on the detected lamp current is carried out, and the output of the secondary sides of the output transformers T71 to T74 is controlled. Surge absorbers SA71 to SA78 are connected to the secondary sides of the output transformer T71 to T74, a high voltage which is generated in the secondary sides of the output transformers is detected by the surge absorber, and the detected high voltage serves as a lamp open-circuit signal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention is for detecting a state in which a lighting fixture is cut off in a lamp lighting device for driving a lighting fixture such as a cold cathode fluorescent lamp or an EL plate (electric luminescence plate) driven on the secondary side of an output transformer. The present invention relates to a lamp open detection circuit.

  Conventionally, when a cold cathode fluorescent lamp is being driven, when the lamp does not light up or breaks and the lamp is open, this is detected, and the secondary voltage of the output transformer is the dielectric strength of the secondary winding. The circuit to stop the output before the output voltage exceeds the limit is obtained by connecting two voltage dividing capacitors in series across the secondary winding of the output transformer T and reading the divided voltage generated in the voltage dividing capacitor. The lamp open state is detected by detecting this from the line and increasing the divided voltage.

As described above, the method of dividing the secondary side of the output transformer with a pair of capacitors uses a capacitor with a high withstand voltage, such as a 3 KV capacitor, which is large and expensive. In this case, the number of lead wires for high-voltage wires increases. In addition, when a winding-type transformer is used as an output transformer and a series resonance circuit is formed on the primary side of the output transformer with L of the primary winding and C of the resonance capacitor, a capacitor for determining the resonance frequency of the primary side The resonance frequency is determined by a pair of capacitors and L of the secondary winding on the secondary side with respect to L of the primary winding. If there is no pair of capacitors, the secondary side resonance frequency C is determined only by the secondary side stray capacitance, but a strong secondary side resonance frequency is set by the pair of capacitors, and this is the primary. There is a problem that the lamp driving efficiency is reduced due to the primary resonance self-excited oscillation.
The present invention aims to solve the above problems.

In order to achieve the above object, the present invention controls on / off of a semiconductor switching element, generates a high-frequency signal, supplies it to the primary side of the output transformer, and turns on the lighting fixture connected to the secondary side of the output transformer. In such a lamp lighting device, a surge absorber is connected to the secondary side of the output transformer, a high voltage generated on the secondary side of the output transformer is detected by the surge absorber, and a lamp open signal is obtained. is there.
Further, in the present invention, the output transformer is a four-output type winding multi-output transformer, and among the secondary windings of the output transformer, terminals having opposite phases of a pair of secondary windings are connected in series. The other terminals of the other pair of secondary windings are connected in series, the midpoint between the connected terminals is grounded through a high resistance element, and the surge absorber is connected to the midpoint Is.
The present invention also provides a plurality of the output transformers, the primary sides of the output transformers are connected in series or in parallel, the surge absorbers are connected to the secondary sides of the output transformers, and the surge absorbers are rectified. A lead wire is connected in parallel via a diode, and a signal wire for detecting lamp open is connected to the lead wire.

  The present invention can detect the lamp open state with a simple configuration. Further, since it is not necessary to provide a voltage dividing capacitor on the secondary side of the output transformer, the cost can be reduced, and the influence on the resonance frequency on the secondary side of the output transformer can be reduced. it can.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 2 shows a lamp driving circuit for a liquid crystal backlight, and semiconductor switching elements Q1, Q2, Q3, and Q4 made of MOSFETs that constitute a bridge output circuit are on / off controlled by an automatic oscillation type high frequency inverter control IC2. The high frequency power is input from the high frequency output terminals 4 and 6 of the bridge output circuit to the primary side input terminals of the wound type four output transformers T71, T72, T73, and T74.

In each of the output transformers T71 to T74, two I-type cores are arranged in parallel and coupled to each other via a bobbin. These two I-type cores are connected by a C-type core, and two I-type cores are connected. And the C-shaped core constitutes a closed magnetic circuit. Each of two parallel I-shaped cores has one primary winding at the center and secondary windings on both sides thereof via bobbins. The primary windings of the output transformers T71 to T74 are connected in series with each other. 1 and no. 4 are connected in parallel to each other, and the No. 4 of the output transformer T71 is connected. 1 and No. The input terminal 4 is connected to the output terminals 4 and 6 of the bridge output circuit. As shown in FIG. 3, the inverter control IC 2 includes an output driver for driving the semiconductor switching elements Q1 to Q4, an output driver control circuit for controlling the output driver, a phase detection circuit, a burst control circuit, and a reference voltage circuit. , A burst oscillation circuit, a PWM control circuit, a PWM control input terminal 8, an overcurrent detection input terminal 9, and a lamp open detection input terminal 10.

The PWM control circuit controls the pulse width supplied from the output driver to the control poles of the semiconductor switching elements Q1 to Q4 based on the DC feedback signal from the load input from the PWM control input terminal 8, and the tube current That is, an operation for keeping the current flowing through the lamp constant is performed. CN71 to CN78 are connectors, and are arranged on the printed circuit board 12 as shown in FIG.

Next, the relationship between the connectors CN71 and CN72 and the corresponding output transformer T71 will be described below with reference to FIG.
Four secondary windings M1, M2, M3, and M4 are provided on the secondary side of the output transformer T71. Among a pair of I-type cores, a pair of windings M1, M2 mounted on one I-type core are connected in series with each other, and a pair of windings M3, M4 mounted on the other I-type cores are also the same. They are connected in series with each other. Of the pair of windings M1 and M2, the No. The terminal 5 is connected to the terminal B of the connector CN71 through the ballast capacitor C71. No. of the other winding M2. The terminal 7 is connected to the terminal C of the connector CN72 through the ballast capacitor C73. No. of winding M1, M2 No. 5 terminal, No. 5 The terminal of No. 7 is in a reverse phase relationship. When the terminal No. 5 is positive, the other No. The terminal 7 is negative. No. No. 6 terminal and No. 6 The 8 terminals are connected in series with each other via a lamp current detection circuit 14 described later.

Of the pair of windings M3 and M4, the No. The ten terminals are connected to the terminal A of the connector CN71 through the ballast capacitor C72. No. of the other winding M4. The 12 terminals are connected to the terminal D of the connector CN72 through the ballast capacitor C74. Nos. Of windings M3 and M4 No. 10 terminal and No. 10 No. 12 terminal is in a reverse phase relationship. When the terminal of 10 is positive, the other No. The 12 terminal is negative. No. 10 terminals, 5 terminals are in phase with each other. No. 12 terminal and No. 12 The seven terminals are in phase with each other. No. No. 9 terminal and No. 9 Eleven terminals are connected in series with each other. The other output transformers T72, T73, and T74 are the same as the windings M1 and M2. 6 and no. The 8 terminals are directly connected without going through the lamp current detection circuit 14. Except for this point, the connection relationship between the output transformer T72 and the connectors CN73 and CN74, the connection relationship between the output transformer T73 and the connectors CN75 and CN76, and the connection relationship between the output transformer T74 and the connectors CN77 and CN78 are as described above. The connection relationship between the transformer T71 and the connectors CN71 and CN72 is the same.

  As shown in FIG. 4, lamps L <b> 1 to L <b> 16 including 16 cold cathode fluorescent lamps are connected to the connectors CN <b> 71 to CN <b> 78. Each pair of lamps L1 and L15, L2 and L16, L3 and L6, L4 and L5, L7 and L10, L8 and L9, L11 and L14, and L12 and L13 are connected in series with each other, and each of these lamps L1 to L16. The secondary windings M1, M2, M3, and M4 of the output transformers T71 to T74 are all connected in series to an energizing circuit that forms one closed loop.

That is, for example, when one of the electrodes S of the lamp L1 is set as the starting point, the lamp energization circuit starts with the electrode S, the lamp L15, the connector CN72, the windings M2 and M1 of the output transformer T1, the connector CN71, the lamp L14, and the lamp L11. , Connector CN74, windings M2, M1 of output transformer T72, connector CN73, lamp L10, lamp L7, connector CN76, windings M2, M1 of output transformer T73, connector CN75, lamp L6, lamp L3, connector CN78, output transformer Windings M2, M1 of T74, connector 77, lamp L2, lamp L16, connector CN72, windings M4, M3 of output transformer T71, connector CN71, lamp L13, lamp L12, connector CN74, winding M4 of output transformer T72 M3, connector CN73, lamp L9 Via the lamp L8, the connector CN76, the windings M4 and M3 of the output transformer T73, the connector CN75, the lamp L5, the lamp L4, the connector CN78, the windings M4 and M3 of the output transformer T74, the connector CN77 and the electrode E of the lamp L1, One closed loop returning to S is formed. As described above, by making the energization circuit of the lamp one closed loop, it is possible to light all the lamps with uniform brightness.

Next, the lamp open detection circuit will be described with reference to FIG.
Nos. Of the output transformers T71 to T74, which are in opposite phase to each other. No. 6 terminal and No. 6 The terminals of No. 8 are connected in series and have a reverse phase relationship. No. 9 terminal and No. 9 Eleven terminals are connected in series. No. No. 6 terminal and No. 6 No. 8 terminal midpoint C; No. 9 terminal and No. 9 The middle point C of the 11 terminals is grounded through high resistances R71 and R72, respectively. No. No. 6 terminal and No. 6 8 terminals, No. 8 No. 9 terminal and No. 9 The 11 terminals are connected in series, and dropped to the ground through the high resistances R71 and R72, respectively. As a result, a voltage corresponding to the current flowing to the ground through the high resistances R71 and R72 is generated at the point C. Theoretically, the point C is zero volt, but has a potential deviated from zero volt due to the imbalance between the secondary windings M1 and M2 and M3 and M4 due to the stray capacitance of the output transformer T71 and the leakage inductor. It is preferable to determine the values of the resistors R71 and R72 so that this potential becomes a safe voltage. However, since the potential at the point C varies depending on the external temperature or the like, in this embodiment, 1 MΩ (1 Mega ohm).

One electrode of each of the surge absorbers SA71 and SA72 is connected to each C point, and the other electrode of each of the surge absorbers SA71 and SA72 is parallel to the signal line 15 via the rectifier diodes D9 and D10. Connected to. A smoothing circuit comprising a capacitor C87 and resistance elements R79 and R80 is connected between the surge absorber SA71 and the rectifying diode D19 connected thereto, and each element of the smoothing circuit is grounded. Similarly, a smoothing circuit including a capacitor C88 and resistance elements R81 and R82 is connected between the surge absorber SA72 and the rectifier diode D10. The signal line 15 is connected to a Zener diode ZD3 for voltage clamping, a capacitor P9 for noise removal, and a resistance element R15 for fixing the potential. The secondary sides of the other output transformers T72 to T74 have the same configuration as the secondary side of the output transformer T71, and rectifier diodes D11 to D16 are connected to the signal line 15 in parallel, respectively.

  In the above-described configuration, each of the output transformers T71 to T72 has a No. No. 6 terminal and No. 6 8 terminals and No. 8 terminal. No. 9 terminal and No. 9 The connection point C between the 11 terminals is apparently zero potential, and no high voltage is applied to the surge absorbers SA71 to SA78, which is in a high impedance state. When any one of the lamps L1 to L16 is cut and the energization circuit of the lamp forming the closed loop is cut off, any of the secondary windings M1 to M4 of the output transformers T71 to T74 exceeds a predetermined value. High voltage is generated. For convenience of explanation, assuming that a high voltage is generated in the secondary winding M1 of the output transformer T71, a high voltage is applied to the surge absorber SA71. When a high voltage exceeding a predetermined value generated in the secondary winding M1 is applied to the surge absorber SA71, the impedance of the surge absorber SA71 rapidly decreases, and a surge current flows through the surge absorber SA71.

This surge current flows through the smoothing circuit, is thereby smoothed and converted into a voltage signal, and a voltage due to the surge current is applied to the rectifier diode D9. The current output from the rectifier diode D9 is supplied to the signal line 15, where it is converted into a voltage signal and the voltage is clamped by the Zener diode ZD3. The voltage signal generated on the signal line 15 is input to the lamp open detection input terminal 10 of the control IC 2 as a lamp open signal. When the lamp open signal is input from the signal line 15, the control IC 2 stops the output of the output driver. The rectifier diodes D9 to D16 constitute an OR circuit, and when any one of the rectifier diodes D9 to D16 is applied with a surge current voltage, a lamp open signal clamped to a predetermined voltage is output to the signal line 15. Is done. In the present embodiment, the lamps L1 to L16 are connected in series to an energizing circuit that forms one closed loop, but the present invention is not particularly limited to this configuration, and there are various types of output transformers. The lamp can be connected and lit by the connection method of the embodiment, and even in that case, the lamp open state can be detected by the lamp open detection circuit shown in FIG.

FIG. 3 is a circuit diagram of a lamp open detection circuit according to the present invention. It is a circuit diagram of a lamp lighting device. It is a block circuit diagram of IC for control. It is explanatory drawing of a lamp lighting device. It is a circuit diagram of a part of a lamp lighting device.

Explanation of symbols

2 Control IC
4 Output 6 Output
8 PWM control input terminal 9 Overcurrent detection input terminal 10 Lamp open detection input terminal 12 Printed circuit board 14 Lamp current detection circuit 15 Signal line

Claims (3)

  In a lamp lighting device that controls on / off of a semiconductor switching element, generates a high-frequency signal, supplies the high-frequency signal to a primary side of an output transformer, and lights a lighting fixture connected to the secondary side of the output transformer. A lamp open detection in a lamp lighting device characterized in that a surge absorber is connected to the secondary side of the transformer, and a high voltage generated on the secondary side of the output transformer is detected by the surge absorber and used as a lamp open signal. circuit.   The output transformer is a four-output-type multi-output transformer, and among the secondary windings of the output transformer, terminals having opposite phases of a pair of secondary windings are connected in series, and the other pair The terminals of opposite phases of the secondary winding are connected in series, the midpoint between the connected terminals is grounded through a high resistance element, and the surge absorber is connected to the midpoint The lamp open detection circuit in the lamp lighting device according to claim 1. A plurality of the output transformers are provided, the primary sides of the output transformers are connected in series or in parallel, the surge absorbers are connected to the secondary sides of the output transformers, and the surge absorbers are read through rectifier diodes. 3. A lamp open detection circuit in a lamp lighting device according to claim 1, wherein the lamp open detection circuit is connected in parallel to a wire, and a signal wire for lamp open detection is connected to the lead wire.

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