KR100878422B1 - Multi-lamp backlight system and method for controlling the operation of the same - Google Patents

Abstract

The present invention relates to a multi-lamp backlight system and an operation control method capable of lighting all of the multiple lamps normally.

The multiple lamp backlight system according to the present invention, the multiple lamp unit; A power supply unit supplying DC power; A transformer comprising a main coil and a sub coil, and converting the DC power into AC power according to a winding ratio of the main coil and the sub coil; In the initial operation, the switching operation is controlled by a control signal having a switching frequency corresponding to an initial operating frequency set higher than the resonance frequency of the transformer, and when a predetermined operating time elapses, it corresponds to a normal operating frequency set lower than the initial operating frequency. A PWM control unit controlling a switching operation with a control signal having a switching frequency; And a switch for switching the DC power of the main coil of the transformer according to a control signal from the PWM control unit.

An operation control method of such a multi-lamp backlight system is proposed.

Multiple lamps, backlight, impedance, electrode, partial lighting

Description

MULTI-LAMP BACKLIGHT SYSTEM AND METHOD FOR CONTROLLING THE OPERATION OF THE SAME}

1 is an operating frequency characteristic diagram of a conventional multiple lamp backlight system.

Figure 2 is a block diagram showing an embodiment of a multiple lamp backlight system according to the present invention.

3 is a flowchart showing an embodiment of a method for controlling operation of a multiple lamp backlight system according to the present invention;

4 is a time chart showing an operation frequency conversion process according to the present invention.

5 is a flowchart illustrating an operation frequency conversion process of FIG. 3.

6 is a frequency characteristic diagram showing an operating frequency conversion process according to the present invention.

Explanation of symbols on the main parts of the drawings

50: multiple lamp unit 100: power supply unit

200: transformer 300: PWM control unit

400: switch fi: initial operating frequency

fr: resonant frequency fo: normal operating frequency

ts: operation time to: initial time

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multiple lamp backlight system applied to an LCD television or the like. In particular, in a multiple lamp backlight system, an initial component operates at a frequency higher than the resonant frequency to increase the component of the multiple lamps, thereby increasing impedance. Due to the equal impedance of the multiple lamps, it is possible to prevent only the low impedance lamps are turned on during the initial operation, and thus to a multiple lamp backlight system and its operation control method capable of lighting all the multiple lamps normally will be.

In general, the length of the lamp of the backlight is increased due to the large size of the LCD TV, and a multi-lamp system that drives a plurality of lamps with one inverter is applied for low-cost manufacturing, and thus, the lamp may be turned on. There are several ways to do this. That is, in order to facilitate lamp lighting, various methods such as soft-start and ignition voltage increase have been mobilized.

In these various methods, there is a possibility that a problem may occur in lighting according to various surrounding conditions such as the frequency of the lamp, and a new method for stable lighting of the lamp is being sought.

The conventional multiple lamp system includes a multiple lamp unit including a plurality of lamps connected in parallel to each other, a power supply unit supplying DC power for AC power required for the multiple lamp unit, a main coil connected to the power supply unit, and the main coil. And a transformer for converting the DC power into AC power according to the winding ratio of the main coil and the subcoil, and a control signal having a switching frequency corresponding to a predetermined operating frequency. A PWM control unit for controlling the switching operation, and a switch for switching the DC power of the main coil of the transformer in accordance with the control signal from the PWM control unit 300.

In such a conventional multiple lamp system, a multiple lamp lighting method employs a method of smoothly lighting a lamp using a method such as a soft-start and an increase in ignition voltage, and furthermore, efficiency has been adopted. In order to increase the voltage, an operating frequency close to the resonance frequency of the transformer is set, and the switch is controlled using this operating frequency as the switching frequency.

FIG. 1 is an operating frequency characteristic diagram of a conventional multiple lamp backlight system. Referring to FIG. 1, a conventional multiple lamp system switches an operating frequency set close to a resonance frequency fr of a transformer from an initial operation to a normal operation. To control the switch.

However, in the conventional multiple lamp system, the switching frequency is controlled in the same manner from the initial operation to the normal operation. In this case, when a plurality of lamps have different impedances, the current flows through a lamp having a relatively low impedance at the beginning of the operation. Since a low lamp is turned on first and the lit lamp has a lower impedance, other lamps having a large impedance cannot be turned on while current is concentrated in the lit lamp.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above problems, and its object is to increase the component components of multiple lamps by operating at a frequency higher than the resonant frequency during initial operation in a multiple lamp backlight system. By equalizing the equivalent impedance of the multiple lamps due to the impedance, it is possible to prevent only the low impedance lamps are turned on during the initial operation, and thus a multiple lamp backlight system and its operation control method capable of lighting all the multiple lamps normally. To provide.

In order to achieve the above object of the present invention, an embodiment of the multiple lamp backlight system according to the present invention, the multiple lamp unit including a plurality of lamps connected in parallel with each other; A power supply unit supplying DC power for AC power necessary for the multiple lamp units; A transformer including a main coil connected to the power supply unit and a sub coil receiving AC power from the main coil, and converting the DC power into AC power according to a winding ratio between the main coil and the sub coil; In the initial operation, the switching operation is controlled by a control signal having a switching frequency corresponding to an initial operating frequency set higher than the resonance frequency of the transformer, and when a predetermined operating time elapses, it corresponds to a normal operating frequency set lower than the initial operating frequency. A PWM control unit controlling a switching operation with a control signal having a switching frequency; And switching the DC power of the main coil of the transformer according to the control signal having the initial operating frequency during the initial operation according to the control signal from the PWM controller, and according to the control signal having the normal operating frequency during the normal operation. It characterized in that it comprises a switch for switching the DC power of the main coil of the transformer.

The PWM control unit may control the switching operation by gradually converting the switching frequency from the initial operating frequency to the normal operating frequency from the initial operation to the elapse of the operation time.

The PWM control unit controls the switching operation with a control signal having the initial operating frequency at an initial operation time point, and passes the initial time from the initial operation time until a predetermined time until the operation time elapses. The switching operation is controlled by a control signal having a switching frequency gradually lowered from the initial operating frequency to the normal operating frequency.

In addition, in order to achieve the object of the present invention, an embodiment of the operation control method of the multiple lamp backlight system according to the present invention, the multiple lamp unit including a plurality of lamps connected in parallel to each other, and the multiple lamp unit A power supply unit for supplying DC power for AC power, a main coil connected to the power supply unit, and a sub-coil for transferring AC power from the main coil, the DC power according to the winding ratio of the main coil and the sub-coil. In the operation control method of a multiple lamp backlight system comprising a transformer for converting the AC power to AC power, and a switch for switching the AC power converted from the main coil to the sub-coil of the transformer, in the initial operation higher than the resonance frequency of the transformer Initial control of the switch using a control signal having a set initial operating frequency as the switching frequency Control step; According to the control signal having the initial operating frequency, the electrode part of each of the plurality of lamps is heated by the high frequency AC power supplied to the multiple lamp part in accordance with the operation of the switch and the transformer to part each of the plurality of lamps. A partial lighting step of being turned on; A switching frequency converting step of converting the switching frequency into a normal operating frequency set higher than the initial operating frequency when a predetermined operating time elapses from the initial operating time; A normal control step of controlling the switch using a control signal having the normal operating frequency as a switching frequency; And a total lighting step of totally lighting each of a plurality of lamps of the multiple lamp parts by low frequency AC power supplied to the multiple lamp parts according to the operation of the switch and transformer according to the control signal having the normal operating frequency. It features.

In the frequency converting step, when the operation time has elapsed since the initial operation, the switching frequency is converted from an initial operating frequency to a normal operating frequency.

The frequency converting step may include determining whether a current time from an initial operation time exceeds a preset initial time; If the current time from the initial operation time exceeds the predetermined initial time, gradually down converting the switching frequency from the initial operating frequency to the normal operating frequency as time passes; If the current time from the initial operation time does not exceed a preset operation time, proceeding to the frequency conversion step; And setting the switching frequency to a normal operating frequency when the current time from the initial operation time exceeds the preset operating time.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is not limited to the embodiments described, and the embodiments of the present invention are used to assist in understanding the technical spirit of the present invention. In the drawings referred to in the present invention, components having substantially the same configuration and function will use the same reference numerals.

2 is a block diagram showing an embodiment of a multiple lamp backlight system according to the present invention.

2, the multi-lamp unit 50 includes a power supply unit 100, a transformer 200, a PWM control unit 300, and a switch 400.

The multiple lamp unit 50 may include a plurality of lamps LP1 to LPn connected in parallel to each other, and the plurality of lamps LP1 to LPn may have different impedances.

The power supply unit 100 supplies DC power for AC power required for the multiple lamp unit. At this time, the DC power supplied is converted into AC power in the transformer 200.

The transformer 200 includes a main coil L1 connected to the power supply unit 100, a sub coil L2 receiving AC power from the main coil L1, and the main coil L1. The DC power is converted to AC power according to the winding ratio of the sub coil L2.

In the initial operation, the PWM controller 300 controls the switching operation with a control signal having a switching frequency corresponding to the initial operating frequency fi set higher than the resonance frequency fr of the transformer 200. When the operation time fs elapses, the switching operation is controlled by a control signal having a switching frequency corresponding to the normal operating frequency fo set lower than the initial operating frequency fi.

The switch 400 is DC power of the main coil (L1) of the transformer 200 in accordance with the control signal having the initial operating frequency (fi) during the initial operation in accordance with the control signal from the PWM control unit (300). In the normal operation, the DC power of the main coil L1 of the transformer 200 is switched according to the control signal having the normal operating frequency fo. At this time, the DC power is converted to the pulsed DC power by the switching of the DC power, the pulsed DC power is converted into AC power through the process to be induced to the sub-coil (L2).

In addition, the PWM control unit 300 gradually converts the switching frequency from the initial operating frequency fi to the normal operating frequency fo from the initial operation until the operation time to elapses, thereby switching operation. Can be controlled.

On the other hand, the PWM control unit 300 controls the pulse width of the control signal having a normal operating frequency on the basis of the detection value of the multi-lamp unit during the normal operation, which will be omitted in the description related to the general PWM control. .

In contrast, the PWM controller 300 controls the switching operation with the control signal having the initial operating frequency fi at the initial operation time, and passes the initial time ts from the initial operation time to the preset time. The switching operation may be controlled by a control signal having a switching frequency gradually lowered from the initial operating frequency fi to the normal operating frequency fo until the operation time fs elapses.

3 is a flowchart showing an embodiment of an operation control method of a multiple lamp backlight system according to the present invention.

2 and 3, in the operation control method of the multi-lamp backlight system, a control signal having an initial operation frequency fi set higher than the resonance frequency fr of the transformer 200 as a switching frequency during an initial operation. The multiple lamp unit in accordance with the operation of the switch 400, the transformer 200 in accordance with the initial control step (S100) for controlling the switch 400 and the control signal having the initial operating frequency (fi) Partial lighting step (S200) in which the electrode portion of each of the plurality of lamps of the multiple lamp unit 50 is heated by the high frequency AC power supplied to 50 to partially light each of the plurality of lamps, and from the initial operation time point. A switching frequency conversion step (S300) of converting the switching frequency to a normal operating frequency fo set higher than the initial operating frequency fi when the predetermined operating time fs elapses, and the positive A normal control step (S400) of controlling the switch using a control signal having a phase operating frequency fo as a switching frequency, and the switch 400 and the transformer 200 according to the control signal having the operating frequency fo. In accordance with the operation of)) by the low-frequency AC power supplied to the multiple lamp unit 50 is composed of a total lighting step (S500) for each of each of the plurality of lamps of the multiple lamp unit (50).

4 is a time chart illustrating an operation frequency conversion process according to the present invention.

2 to 4, in the frequency conversion step S300, the switching frequency is changed from the initial operating frequency fi to the normal operating frequency fo from the initial operation until the operation time to elapses. To gradually convert.

5 is a flowchart illustrating an operation frequency conversion process of FIG. 3.

Referring to FIG. 5, the frequency converting step S300 may include determining whether the current time exceeds a preset initial time ts from an initial operation point (S10), and the current time from the initial operation point. When the initial time ts is exceeded, the step of gradually converting the switching frequency from the initial operating frequency fi to the normal operating frequency fo as time passes (S320) and from the initial operation time point If the current time does not exceed the preset operating time (to), the process proceeds to the frequency conversion step (S330), and if the current time exceeds the operating time (to) from the initial operation time, the switching frequency is operated normally. It may be a step (S340) to set to the frequency (fo).

6 is a frequency characteristic diagram showing an operating frequency conversion process according to the present invention.

Referring to FIG. 6, as described above, it is shown that the switching frequency is converted from the initial operating frequency fi having a relatively high frequency to the normal operating frequency fo having a relatively low frequency.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, a multi-lamp backlight system of the present invention will be described. First, the multi-lamp unit 50 of the multi-lamp backlight system includes a plurality of lamps LP1 to LPn connected in parallel with each other. 100 supplies DC power to the transformer 200 for AC power required for the multiple lamp unit 50.

The transformer 200 converts the DC power from the power supply unit 100 into AC power. That is, the switch 400 includes a main coil L1 connected to the power supply unit 100, a sub coil L2 receiving AC power from the main coil L1, and is connected to the main coil L1. In accordance with the winding ratio of the main coil (L1) and the sub-coil (L2) to convert the DC power to AC power.

Meanwhile, the PWM controller 300 of the present invention controls the switching operation with a control signal having a switching frequency corresponding to the initial operating frequency fi set higher than the resonance frequency fr of the transformer 200 during the initial operation. do.

Accordingly, as the switch 400 switches the connection between the main coil L1 of the transformer 200 and the ground, the DC power input to the main coil L1 of the transformer 200 is pulsed DC. The pulsed DC power is converted into AC power while being induced from the main coil L1 to the subcoil L2. Accordingly, the transformer 200 supplies high-frequency AC power to electrode portions of each of the plurality of lamps LP1 to LPn of the multiple lamp portion 50.

In this case, since the AC power of the high frequency has a high frequency in each of the electrode units of the plurality of lamps LP1 to LPn of the multiple lamp unit 50, the high frequency AC power is emitted as a liquid component through the chassis of the system to which the present invention is applied. A capacitor is generated between the electrode part and the chassis due to the generation of the liquid crystal. As the frequency of the AC power increases through the capacitor, the liquid crystal component increases. As the liquid crystal component increases, the impedance of the electrode portion and the chassis is increased. Becomes smaller.

Here, the electrode of each of the plurality of lamps LP1 to LPn and the capacitors of the chassis are connected in parallel with each other in impedance of the lamps, and the difference in impedance when a small impedance is connected in parallel with the impedance of the lamps. Will be significantly reduced.

For example, assuming that the two lamps have impedances of 100 and 200 ohms, the impedances of the two lamps are about twice as large as each other, but when the impedances of 10 Ω are connected to the two lamps in parallel, one equivalent impedance is approximately 9.0 Ω (100/11 = (100 * 10) / (100 + 10)) and 9.5Ω (200/21 = (200 * 10) / (200 + 10)). That is, compared with the impedance of the two lamps themselves, it can be seen that there is almost no difference in impedance between the lamps due to the generation of the leakage.

As described above, the plurality of lamps LP1 to LPn of the multiple lamp unit 50 are heated while generating a liquid component in each electrode unit, and thus instantaneously decrease efficiency, but impedance to each other for more stable lighting. Are almost the same, and all the electrode portions of the plurality of lamps are turned on.

Then, the PWM control unit 300 of the present invention, as shown in Figure 4, when the predetermined operating time fs elapses, the switching corresponding to the normal operating frequency (fo) is set lower than the initial operating frequency (fi) The switching operation is controlled by a control signal having a frequency.

Accordingly, the switch 400 according to a control signal having a switching frequency corresponding to the normal operating frequency (fi) in the transformer 200 a plurality of lamps of the high-frequency AC power of the multiple lamp unit 50 Supply to each of (LP1 to LPn).

At this time, each of the plurality of lamps LP1 to LPn of the multiple lamp unit 50 is entirely turned on by the AC power of the low frequency.

On the other hand, the PWM control unit 300 controls the switching operation with a control signal having the initial operating frequency (fi) at the initial operation time, the operation time (fs) from the time when a predetermined initial time (ts) elapses The switching operation may be controlled by a control signal having a switching frequency gradually lowered from the initial operating frequency fi to the normal operating frequency fo.

An operation control method of the multiple lamp backlight system according to the present invention will be described with reference to FIGS. 2 to 6. Here, the content duplicated with the content described with reference to FIG. 2 is omitted as possible.

Referring to FIG. 3, in the operation control method of the multi-lamp backlight system of the present invention, first, in the initial control step, as shown in FIG. 6, the initial operation is higher than the resonance frequency fr of the transformer 200. The switch 400 is controlled using a control signal having the set initial operating frequency fi as a switching frequency (corresponding to S100 of FIG. 3).

Here, the setting of the initial operating frequency is to reduce the impedance of each electrode unit and the time of the multiple lamp unit 50 as described above.

Next, in the partial lighting step, the high frequency AC power is supplied to the multiple lamp unit 50 according to the operation of the switch 400 and the transformer 200 in accordance with the control signal having the initial operating frequency fi. The electrode portion of each of the plurality of lamps of the multiple lamp portion 50 is heated to partially light each of the plurality of lamps (corresponding to S200 of FIG. 3).

In this case, the AC power of the high frequency is discharged as a liquid component through the chassis of the system to which the present invention is applied in each of the plurality of lamps LP1 to LPn of the multiple lamp unit 50. Therefore, a capacitor is generated between the electrode portion and the chassis, and the capacitor increases as the frequency of the AC power increases, and decreases as the increase in the liquid component increases.

Accordingly, the electrode of each of the plurality of lamps LP1 to LPn and the capacitors of the chassis are connected in parallel with the impedance of each lamp, and when a small impedance is connected in parallel with the impedance of the lamp, The difference is almost gone.

Next, as shown in FIG. 4, in the switching frequency conversion step, when a predetermined operating time fs has elapsed from the initial operation time, the normal operating frequency set to be higher than the initial operating frequency fi ( fo) (corresponding to S300 of FIG. 3).

That is, referring to FIG. 6, in the frequency conversion step, when the operation time to elapses from the initial operation, the switching frequency may be converted from the initial operating frequency fi to the normal operating frequency fo. In this case, the normal operating frequency fo may be set to a resonance frequency or a frequency near the resonance frequency in order to increase the conversion efficiency of the transformer.

Next, in the normal control step, the switch is controlled using a control signal having the normal operating frequency fo as the switching frequency (corresponding to S400 of FIG. 3).

And, in the entire lighting step, the multiple by the low-frequency AC power supplied to the multiple lamp unit 50 in accordance with the operation of the switch 400, the transformer 200 in accordance with the control signal having the operating frequency (fo) Each of the plurality of lamps of the lamp unit 50 is turned on (corresponding to S500 of FIG. 3).

The frequency conversion step S300 will be described with reference to FIG. 5.

In the first step of the frequency conversion step (S300), it is determined whether the current time from the initial operation time exceeds a predetermined initial time (ts) (S310). In the next second step, when the current time from the initial operation time exceeds the predetermined initial time ts, the switching frequency is gradually increased from the initial operating frequency fi as the normal operating frequency fo as time passes. Down conversion is to (S320). In the next third step, if the current time from the initial operation time does not exceed the preset operation time (to), the process proceeds to the frequency conversion step (S330). In the fourth step, when the current time from the initial operation time exceeds the predetermined operation time to, the switching frequency is set to the normal operating frequency fo (S340).

As described with reference to FIG. 5, the switching frequency of the present invention starts from a relatively high initial operating frequency fi, as shown in FIG. 6, and moves toward a relatively low normal operating frequency fo. In this case, the normal operating frequency may be set to a resonance frequency or a frequency near the resonance frequency in order to increase the conversion efficiency of the transformer.

In the present invention as described above, the impedance of the plurality of lamps is equivalently seen at the beginning of operation by using a high frequency which is not used for reducing the efficiency of the transformer in the multiple lamps so that all of the plurality of lamps are turned on. After that, the frequency is lowered in the resonant frequency direction so that a plurality of lamps can be stably lit using the normal frequency.

According to the present invention as described above, in a multiple lamp backlight system applied to an LCD television or the like, at the initial operation, operating at a frequency higher than the resonant frequency increases the component of the multiple lamps, By making the equivalent impedance of the lamp the same, it is possible to prevent only the lamp of the low impedance during the initial operation to be turned on, and thus there is an effect that all of the multiple lamps can be turned on normally.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, but is defined by the claims, and the apparatus of the present invention may be substituted, modified, and modified in various ways without departing from the spirit of the present invention. It is apparent to those skilled in the art that modifications are possible.

Claims (6)

Multiple lamp unit including a plurality of lamps connected in parallel with each other; A power supply unit supplying DC power for AC power necessary for the multiple lamp units; A transformer including a main coil connected to the power supply unit and a sub coil receiving AC power from the main coil, and converting the DC power into AC power according to a winding ratio between the main coil and the sub coil; In the initial operation, the switching operation is controlled by a control signal having a switching frequency corresponding to an initial operating frequency set higher than the resonance frequency of the transformer, and when a predetermined operating time elapses, it corresponds to a normal operating frequency set lower than the initial operating frequency. A PWM control unit controlling a switching operation with a control signal having a switching frequency; And In the initial operation according to the control signal from the PWM control unit, the DC power of the main coil of the transformer is switched according to the control signal having the initial operating frequency, and in the normal operation according to the control signal having the normal operating frequency Switch to switch the DC power of the transformer's main coil Multiple lamp backlight system comprising a. The method of claim 1, wherein the PWM control unit, And controlling the switching operation by gradually converting the switching frequency from the initial operating frequency to the normal operating frequency from the initial operation to the elapse of the operation time. The method of claim 1, wherein the PWM control unit, In the initial operation time, the switching operation is controlled by the control signal having the initial operating frequency, and gradually increases at the initial operating frequency from the time when the initial time passes from the initial operation time to the preset time until the operation time passes. And controlling a switching operation with a control signal having a switching frequency lowered to the normal operating frequency. A multiple lamp unit including a plurality of lamps connected in parallel to each other, a power supply unit supplying DC power for AC power required for the multiple lamp units, a main coil connected to the power supply unit, and AC power from the main coil And a transformer for converting the DC power into AC power according to the winding ratio of the main coil and the subcoil, and a switch for switching the AC power converted from the main coil of the transformer to the subcoil. In the operation control method of the lamp backlight system, An initial control step of controlling the switch by using a control signal having an initial operating frequency set as a switching frequency higher than a resonance frequency of the transformer during an initial operation; According to the control signal having the initial operating frequency, the electrode part of each of the plurality of lamps is heated by the high frequency AC power supplied to the multiple lamp part in accordance with the operation of the switch and the transformer to part each of the plurality of lamps. A partial lighting step of being turned on; A switching frequency conversion step of converting the switching frequency into a normal operating frequency set higher than the initial operating frequency when a predetermined operating time elapses from the initial operating time A normal control step of controlling the switch using a control signal having the normal operating frequency as a switching frequency; And A total lighting step of totally lighting each of a plurality of lamps of the multiple lamp parts by low frequency AC power supplied to the multiple lamp parts according to the operation of the switch and transformer according to the control signal having the normal operating frequency; Operation control method of a multiple lamp backlight system comprising a. The method of claim 4, wherein the frequency conversion step, And when the operation time elapses from the initial operation, converting the switching frequency from an initial operating frequency to a normal operating frequency. The method of claim 4, wherein the frequency conversion step, Determining whether a current time from an initial operation time exceeds a preset initial time; If the current time from the initial operation time exceeds the predetermined initial time, gradually down converting the switching frequency from the initial operating frequency to the normal operating frequency as time passes; If the current time from the initial operation time does not exceed a preset operation time, proceeding to the frequency conversion step; And Setting the switching frequency to the normal operating frequency when the current time from the initial operation time exceeds the preset operating time. Operation control method of a multiple lamp backlight system, characterized in that consisting of.

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