KR200459232Y1 - Backlight module and inverter circuit thereof - Google Patents

Abstract

The technical problem of the present invention is to provide a backlight having an electric light and an inverter circuit provided on a single-layer circuit board. An inverter circuit for a backlight of the present invention includes a transformer including a primary coil and a secondary coil, a high voltage copper foil electrically connected between the high voltage terminal of the secondary coil of the transformer and the lamp, and the primary coil of the transformer. An electrical conversion circuit electrically connected to the electrical signal and converting the introduced electrical signal into an AC signal, a detection circuit detecting a voltage of the high voltage terminal of the secondary coil of the transformer and including a sensitive copper thin film and a resistance member; A protection circuit electrically connected between the sensitive copper thin film and the resistance member and outputting one protection signal in accordance with the divided voltage response; and a protection signal electrically connected between the protection circuit and the electrical conversion circuit according to the input signal. And a PWM control device for controlling the output of the electrical conversion circuit.

Description

Inverter Circuit for Backlight and Backlight {BACKLIGHT MODULE AND INVERTER CIRCUIT THEREOF}

The present invention relates to an inverter circuit for driving a backlight and a lamp installed in the backlight.

Discharge lamps such as Cold Cathode Fluorescent Lamps (CCFLs) are widely used as light sources of backlights of liquid crystal displays (LCDs). A discharge lamp such as a cold cathode fluorescent lamp may emit light normally only when driven by an inverter circuit. In addition, the inverter circuit is provided with a voltage detection circuit and a protection circuit so that the discharge lamp always emits light normally.

1 is a circuit diagram of a backlight inverter circuit according to the prior art. The inverter circuit includes an electric conversion circuit 10, a protection circuit 12, a PWM control device (control member; 13), a transformer T1, a capacitor C11, a capacitor C12, and a discharge lamp L1. Include.

The electric conversion circuit 10 converts the introduced electric signal into an AC signal. The transformer T1 is electrically connected to the electric conversion circuit 10 to transform an AC signal of the electric conversion circuit 10 into an electric signal for driving the discharge lamp L1. The capacitors C11 and C12 are connected in series between the high voltage terminal of the secondary coil of the transformer T1 and the ground to divide the voltage of the secondary coil. One end of the protection circuit 12 is electrically connected between the capacitors C11 and C12 to output one protection signal by comparing the divided voltages of the capacitors and the reference voltage. The PWM control device 13 is electrically connected between the electric conversion circuit 10 and the protection circuit 12 to control the output of the electric conversion circuit 10 according to the protection signal of the protection circuit 12. do.

The inverter circuit divides the voltage at the high voltage stage of the transformer secondary coil using a high voltage capacitor and a low voltage capacitor (ie, capacitors C11 and C12). However, since the high voltage capacitor is an expensive electronic member, the manufacturing cost of the inverter circuit can be greatly increased. In addition, since the inverter circuit is provided on a multilayer circuit board, and the high voltage capacitor is formed by a copper thin film of the multilayer circuit board, the manufacturing cost of the inverter circuit can be further increased.

For this reason, there is a need for a backlight not only having a protective function but also forming a high voltage capacitor from a copper thin film of a single-layer circuit board, which can reduce manufacturing costs.

In addition, the inverter circuit is provided on the single-layer circuit board for driving the backlight lamp.

It is a main object of the present invention to provide a backlight capable of reducing manufacturing costs by forming a high voltage capacitor with a copper thin film of a single layer circuit board as well as a protective function.

In addition, another object of the present invention is to provide an inverter circuit provided on the single-layer circuit board for driving the lamp of the backlight.

The first technical problem of the present invention is to provide a backlight having an electric light and an inverter circuit installed on a single-layer circuit board. The backlight inverter circuit includes a transformer, a high voltage copper thin film, an electric conversion circuit, a detection circuit, a protection circuit, and a PWM control device. The transformer has a primary side coil and a secondary side coil. The high pressure copper thin film is electrically connected between the high voltage terminal of the secondary coil of the transformer and the lamp. The electrical conversion circuit is electrically connected to the primary coil of the transformer to convert the introduced electrical signal into an AC signal. The detection circuit detects the voltage of the high voltage terminal of the secondary coil of the transformer. The detection circuit is provided with a predetermined distance from the high voltage copper thin film, and together with the high pressure copper thin film, a sensitive copper thin film constituting an equivalent circuit for inducing the voltage of the high voltage terminal of the secondary coil of the transformer; And a resistance member electrically connected between the sensitive copper thin film and the ground to divide the sensed voltage and form one ground reference phase. One end of the protection circuit is electrically connected between the sensitive copper thin film and the resistance member to output one protection signal according to the divided voltage. The PWM control device is electrically connected between the protection circuit and the electric conversion circuit to control the output of the electric conversion circuit in accordance with the input protection signal.

A second technical problem of the present invention is to provide a backlight having a plurality of lights and an inverter circuit installed on a single layer circuit board. The backlight inverter circuit includes at least a pair of transformers, two high voltage copper thin films, an electric conversion circuit, a detection circuit, a protection circuit, and a PWM control device. Each transformer is provided with two high voltage output stages for outputting two primary coils and two voltages having different phases. The high pressure copper thin film is electrically connected between the corresponding high pressure output terminal and the lamp. The electrical conversion circuit is electrically connected to the primary coil of the transformer to convert the introduced electrical signal into an AC signal. The detection circuit detects the voltage of the high voltage terminal of the secondary coil of the transformer. The detection circuit comprises at least one sensitive copper thin film which is provided between the two high voltage copper foils and constitutes two equivalent circuits which, together with the high pressure copper thin film, sense the voltage at the high voltage end of the secondary coil of the transformer; And a resistance member electrically connected between the sensitive copper thin film and the ground to divide the sensed voltage and form one ground reference phase. One end of the protection circuit is electrically connected between the sensitive copper thin film and the resistance member to output one protection signal according to the divided voltage. The PWM controller is connected between the protection circuit and the electrical conversion circuit to control the output of the electrical conversion circuit in accordance with the input protection signal. The distance between the sensitive copper thin film and the two high pressure copper thin films is the same.

The third technical problem of the present invention is to provide an inverter circuit installed on a single layer circuit board to drive a lamp. The inverter circuit includes a transformer, a high voltage copper thin film, an electric conversion circuit, a detection circuit, a protection circuit, and a PWM control device. The transformer has a primary side coil and a secondary side coil. The high pressure copper thin film is electrically connected between the high voltage terminal of the secondary coil of the transformer and the lamp. The electrical conversion circuit is electrically connected to the primary coil of the transformer to convert the introduced electrical signal into an AC signal. The detection circuit detects the voltage of the high voltage terminal of the secondary coil of the transformer. The detection circuit is provided at a predetermined distance from the high-voltage copper thin film, and together with the high-pressure copper thin film, a sensitive copper thin film constituting an equivalent circuit for sensing the voltage at the high voltage terminal of the secondary coil of the transformer, and the sensitive copper thin film. And a resistance member electrically connected between the thin film and the ground to divide the sensed voltage and form one ground reference phase. One end of the protection circuit is electrically connected between the sensitive copper thin film and the resistance member to output one protection signal according to the divided voltage. The PWM control device includes a PWM control device connected between the protection circuit and the electrical conversion circuit to control the output of the electrical conversion circuit according to the input protection signal.

The fourth technical problem of the present invention is to provide an inverter circuit installed on a single layer circuit board to drive a plurality of lights. The inverter circuit includes at least a pair of transformers, two high voltage copper thin films, an electric conversion circuit, a detection circuit, a protection circuit, and a PWM control device. Each transformer has two high voltage output stages for outputting two primary coils and two voltages having different phases. The high pressure copper thin film is electrically connected between the corresponding high pressure output terminal and the lamp. The electrical conversion circuit is electrically connected to the primary coil of the transformer to convert the introduced electrical signal into an AC signal. The detection circuit detects the voltage of the high voltage terminal of the secondary coil of the transformer. The detection circuit comprises at least one sensitive copper thin film which is provided between the two high voltage copper foils and constitutes two equivalent circuits which, together with the high pressure copper thin film, sense the voltage at the high voltage end of the secondary coil of the transformer; And a resistance member electrically connected between the sensitive copper thin film and the ground to divide the sensed voltage and form one ground reference phase. One end of the protection circuit is electrically connected between the sensitive copper thin film and the resistance member to output one protection signal according to the divided voltage. The PWM controller is connected between the protection circuit and the electrical conversion circuit to control the output of the electrical conversion circuit in accordance with the input protection signal. The distance between the sensitive copper thin film and the two high pressure copper thin films is the same.

According to the present invention, the backlight inverter circuit of the present invention is installed on a single-layer circuit board, and forms a high-voltage sensitive capacitor using the sensitive copper thin film and the high-pressure copper thin film of the single-layer circuit board. Since the high voltage sensitive capacitor can sense the voltage at the high voltage stage of the transformer secondary coil as well as the high voltage capacitor of the prior art, it is possible to detect the voltage while performing a partial pressure with the resistance member. It is possible to reduce the manufacturing cost of the backlight inverter circuit than in the case. Therefore, the manufacturing cost of the backlight can also be reduced.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail with reference to FIGS.

2 is a circuit diagram of an inverter circuit for a backlight 200 according to the first embodiment of the present invention. The backlight 200 includes an inverter circuit 20 and a lamp L2. The inverter circuit 20 is installed on a single layer circuit board to drive the lamp L2. The inverter circuit 20 includes an electric conversion circuit 21, a transformer T2, a detection circuit 22, a protection circuit 23, a high voltage copper thin film P21, and a PWM control device (control member) 24. . The detection circuit 22 includes an induction copper thin film P22 and a resistance member Z2.

The electric conversion circuit 21 converts the introduced electric signal into an AC signal. The transformer T2 includes a primary coil and a secondary coil, and transforms the AC signal into an electrical signal for driving the lamp L2. The primary coil of the transformer T2 is electrically connected to the electrical conversion circuit 21, and the high voltage terminal of the secondary coil is electrically connected to the lamp L2 through the high pressure copper thin film P21. The low voltage terminal of the secondary coil is grounded.

The sensitive copper thin film P22 and the high pressure copper thin film P21 are provided to face each other at a predetermined distance. Here, a predetermined distance means the distance which an electric flame does not generate | occur | produce between the sensitive copper thin film P22 and the high pressure copper thin film P21. Since an equivalent capacitor C2 is formed in the sensitive copper thin film P22 and the high voltage copper thin film P21, the voltage of the high voltage output terminal of the secondary coil of the transformer T2 can be sensed. The resistance member Z2 is electrically connected between the sensitive copper thin film P22 and the ground. That is, the resistance member Z2 is electrically connected between the equivalent capacitor C2 and the ground to divide the voltage sensed by the equivalent capacitor C2 and form a grounded reference phase.

One end of the protection circuit 23 is electrically connected between the sensitive copper thin film P22 and the resistance member Z2 to compare the voltage divided by the resistance member Z2 with a reference voltage to compare one protection signal. Outputs

The PWM control device 24 is electrically connected between the protection circuit 23 and the electric conversion circuit 21 to control the output of the electric conversion circuit 21 according to the protection signal of the protection circuit 23. do. In the present embodiment, the protection circuit 23 is an overvoltage protection circuit. That is, when an overvoltage is applied to the lamp L2, the PWM control device 24 adjusts the voltage of the lamp L2 so that the lamp L2 is not damaged according to the protection signal of the protection circuit 23. To control.

3 is a circuit diagram of an inverter circuit for the backlight 300 according to the second embodiment of the present invention. The backlight 300 includes an electric conversion circuit (not shown), a PWM control device (not shown), two transformers T3 and T3 ', two high-pressure copper thin films P31 and P33, and a detection circuit 32. ), The protection circuit 33 and the like. The detection circuit 32 includes a sensitive copper thin film P32 and a resistance member Z3. The high voltage ends of the secondary coils of the two transformers T3 and T3 'are electrically connected to the two lamps L31 and L32 through the two high pressure copper thin films P31 and P33, respectively.

The sensitized copper thin film P32 is positioned between the two high pressure copper thin films P31 and P33, and the distance between the sensitized copper thin film P32 and the two high pressure copper thin films P31 and P33 is equal to each other. For this reason, an equivalent capacitor C31 is formed between the sensitive copper thin film P32 and the high pressure copper thin film P31, and the equivalent capacitor C31 and the same between the sensitive copper thin film P32 and the high pressure copper thin film P33. An equivalent capacitor C32 having the same specification (capacity) is formed. The resistance member Z3 is electrically connected between the sensitive copper thin film P32 and the ground to divide the voltage sensed by the sensitive copper thin film P32 and form a grounded reference phase. One end of the protection circuit 33 is electrically connected between the sensitive copper thin film P32 and the resistance member Z3 to compare the voltage divided by the resistance member Z3 with the reference voltage to protect one signal. Outputs

In the present embodiment, the voltages at the high voltage terminals of the secondary coils of the transformers T3 and T3 'are Vo + and Vo-, respectively. These voltages, Vo + and Vo-, are the same magnitude but differ in phase. When the lamps L31 and L32 emit light normally, no voltage is applied to the protection circuit 33. On the other hand, when an abnormal (abnormal) situation appears in the lamp L31 or L32, a voltage is applied to the protection circuit 33. In this way, the protection circuit 23 determines the state of the lamps L31 and L32 in accordance with the presence or absence of the applied voltage. If an abnormal situation appears in the lamp L31 or L32, the protection circuit 23 may turn off the entire circuit.

In the said embodiment, by making the distance between the sensitive copper thin film P32 and the two high pressure copper thin films P31 and P33 the same, the specification (capacity) of the two equivalent capacitors C31 and C32 becomes the same, and the resistance member ( The voltage divided by Z3) is made equal. Accordingly, the detection circuit 32 may detect voltages applied to two lamps having different polarities and adjacent to each other.

In this embodiment, one detection circuit 32 corresponds to two transformers T3 and T3 '. That is, when N transformers are installed in the backlight 300, N / 2 detection circuits 32 should be provided, but only one protection circuit 33 needs to be provided.

4 is a circuit diagram of an inverter circuit for a backlight 400 according to a third embodiment of the present invention. Differences between FIG. 3 and FIG. 4 are as described below. The detection circuit 42 shown in FIG. 4 includes two sensitive copper thin films P42 and P43. These two sensitive copper thin films P42 and P43 and two high pressure copper thin films P41 and P44 form two sensitive capacitors C41 and C42. These sensitive capacitors C41 and C42 sense the voltage at the high voltage stage of the secondary coil stage of the transformers T4 and T4 ', respectively. In this way, the detection circuit 42 can detect voltages applied to two lamps having different polarities and not adjacent to each other.

1 is a circuit diagram of an inverter circuit for a backlight according to the prior art,

2 is a circuit diagram of a backlight inverter circuit according to a first embodiment of the present invention;

3 is a circuit diagram of a backlight inverter circuit according to a second embodiment of the present invention;

4 is a circuit diagram of a backlight inverter circuit according to a third embodiment of the present invention.

<Explanation of reference number>

200, 300, 400... Backlight

20... Inverter circuit

21. Electrical conversion circuit

T2, T3, T3 ', T4, T4'... Transformers

22, 32, 42... Detection circuit

C1, C31, C32, C41, C42... Capacitor

L2, L31, L32, L41, L42... light

Z2, Z3, Z4... resistance

P21, P31, P33, P41, P44... High pressure copper film

(P22), P32, P42, P43... Induction copper foil

23, 33, 43... Protection circuit

24. PWM controller

Claims (6)

In the backlight having an electric light and an inverter circuit provided on a single-layer circuit board, The inverter circuit, A transformer having a primary coil and a secondary coil; A high pressure copper thin film electrically connected between the high voltage stage of the secondary coil of the transformer and the lamp; An electrical conversion circuit electrically connected to the primary coil of the transformer and converting the introduced electrical signal into an AC signal; A sensitive copper thin film which is provided at a predetermined distance from the high voltage copper thin film and constitutes an equivalent circuit for sensing the voltage of the high voltage terminal of the secondary coil of the transformer together with the high voltage copper thin film, and between the sensitive copper thin film and the ground. A detection circuit electrically connected to the voltage divider for dividing the sensed voltage and forming a ground reference phase, the detecting circuit detecting a voltage of the high voltage terminal of the secondary coil of the transformer; A protective circuit having one end electrically connected between the sensitive copper thin film and the resistance member and outputting one protective signal according to the divided voltage; And a PWM control device electrically connected between the protection circuit and the electric conversion circuit to control an output of the electric conversion circuit in accordance with an input protection signal. The backlight of claim 1, wherein the low voltage terminal of the secondary coil of the transformer is grounded. In the backlight having a plurality of lights and an inverter circuit provided on a single layer circuit board, The inverter circuit, At least one transformer having two primary coils and two high voltage output stages for outputting two voltages out of phase for each transformer, Two high-pressure copper foils electrically connected between corresponding high-voltage output stages and the lamps; An electrical conversion circuit electrically connected to the primary coil of the transformer and converting the introduced electrical signal into an AC signal; At least one sensitized copper thin film which is provided between the two high pressure copper thin films and constitutes two equivalent circuits for sensitizing the voltage at the high voltage end of the secondary coil of the transformer together with the high pressure copper thin film; A detecting circuit electrically connected between the ground and the ground to divide the sensed voltage and form a ground reference phase, the detecting circuit detecting a voltage of the high voltage terminal of the secondary coil of the transformer; A protective circuit having one end electrically connected between the sensitive copper thin film and the resistance member and outputting one protective signal according to the divided voltage; A PWM control device electrically connected between the protection circuit and the electrical conversion circuit to control the output of the electrical conversion circuit according to an input protection signal, And a distance between the sensitive copper thin film and the two high pressure copper thin films is equal to each other. In the inverter circuit installed on a single-layer circuit board for driving a light, A transformer having a primary coil and a secondary coil; A high pressure copper thin film electrically connected between the high voltage stage of the secondary coil of the transformer and the lamp; An electrical conversion circuit electrically connected to the primary coil of the transformer and converting the introduced electrical signal into an AC signal; A sensitive copper thin film which is provided at a predetermined distance from the high voltage copper thin film and constitutes an equivalent circuit for sensing the voltage of the high voltage terminal of the secondary coil of the transformer together with the high voltage copper thin film, and between the sensitive copper thin film and the ground. A detection circuit electrically connected to the voltage divider for dividing the sensed voltage and forming a ground reference phase, the detecting circuit detecting a voltage of the high voltage terminal of the secondary coil of the transformer; A protective circuit having one end electrically connected between the sensitive copper thin film and the resistance member and outputting one protective signal according to the divided voltage; And a PWM control device electrically connected between the protection circuit and the electric conversion circuit to control the output of the electric conversion circuit in accordance with an input protection signal. 5. The inverter circuit according to claim 4, wherein the low voltage terminal of the secondary coil of the transformer is grounded. In the inverter circuit installed on a single layer circuit board to drive a plurality of lights, At least one transformer having two primary coils and two high voltage output stages for outputting voltages out of phase for each transformer; Two high-pressure copper foils electrically connected between corresponding high-voltage output stages and the lamps; An electrical conversion circuit electrically connected to the primary coil of the transformer and converting the introduced electrical signal into an AC signal; At least one sensitized copper thin film which is provided between the two high pressure copper thin films and constitutes two equivalent circuits for sensitizing the voltage at the high voltage end of the secondary coil of the transformer together with the high pressure copper thin film; A detecting circuit electrically connected between the ground and the ground to divide the sensed voltage and form a ground reference phase, the detecting circuit detecting a voltage of the high voltage terminal of the secondary coil of the transformer; A protective circuit having one end electrically connected between the sensitive copper thin film and the resistance member and outputting one protective signal according to the divided voltage; A PWM control device electrically connected between the protection circuit and the electric conversion circuit to control an output of the electric conversion circuit according to an input protection signal, Inverter circuit, characterized in that the distance between the sensitive copper thin film and the two high-pressure copper thin film is the same.

Images