KR100586984B1 - plasma display panel - Google Patents

Abstract

The present invention relates to a plasma display panel, and more particularly, to a panel capacitor including a first discharge electrode and a second discharge electrode, and a power connection switch for connecting the first discharge electrode to a power supply. And a ground connection switch for connecting the first discharge electrode to the ground terminal, the plasma display panel comprising: a first switch for switching the connection between the power supply unit and the first discharge electrode and for switching the connection between the ground terminal and the first discharge electrode; A switching unit; A first capacitor connected in series between the power supply unit and the first discharge electrode by a first switching unit when the power connection switch is turned on; A second switching unit for switching a connection between the other end of the second capacitor and the second discharge electrode; When the power connection switch is turned on, the power supply unit and the first discharge electrode are connected, and when the ground connection switch is turned on, the first switching unit is controlled to connect the ground terminal and the first discharge electrode, and the power supply unit and the first discharge electrode are connected. And a switching controller for controlling the second switching unit so that the other end of the second capacitor and the second discharge electrode are connected to each other. As a result, power consumption of the plasma display panel can be reduced.

Driving circuit, power consumption

Description

Plasma display panel

1 is a driving circuit diagram of a conventional plasma display panel;

2 shows a waveform of a sustain pulse applied to an X electrode,

3 is a driving circuit diagram of a plasma display panel according to an embodiment of the present invention;

FIG. 4 shows waveforms of sustain pulses applied to the X electrode shown in FIG.

* Explanation of symbols for main parts of the drawings

1, 101: X driver 2, 102: Y driver

Cp: Panel Capacitor Cs: Energy Recovery Capacitor

D1 ~ D4: Diode Cg: Capacitor for Discharge Current Recovery

S1 ~ S12: Switch L: Inductor

The present invention relates to a plasma display panel.

1 is a driving circuit diagram of a conventional plasma display panel.

As shown in Fig. 1, the driving circuit has a panel capacitor Cp, an X driver 101 and a Y driver 102.

In the panel capacitor Cp, a pair of discharge electrodes constituting a light emitting cell of a pixel and having a predetermined capacitance is modeled as an equivalent capacitor. The discharge electrode of the pixel is an electrode to which a sustain pulse is applied to maintain the discharge of the gas provided in each cell. Hereinafter, the discharge electrodes constituting the panel capacitor Cp will be referred to as X electrodes and Y electrodes, respectively.

The X driver 101 and the Y driver 102 have the same circuit configuration for applying sustain pulses to the X electrode and the Y electrode, respectively. That is, the X driver 101 and the Y driver 102 have energy recovery capacitors Cs, switches S1-S8, diodes D1-D4, and inductor L.

The operations of the X driver 101 and the Y driver 102 also symmetrically coincide. For example, when the X driver 101 applies the sustain pulse to the X electrode, the Y electrode is connected to the reference contact point of the Y driver 102, and symmetrically, the Y driver 102 applies the sustain pulse to the Y electrode. When applied, the X electrode is connected to the reference contact of the X driver 101.

Figure 2 shows the waveform of the sustain pulse applied to the X electrode.

1 and 2, the process of applying the sustain pulse to the X electrode will be described in detail together with the switching control process of the circuit.

[V]의 전압으로 초기 충전되어 있다. First, the capacitor of the X driver 101

It is initially charged with the voltage of [V].

With all switches open, switches S1 and S6 are closed. Accordingly, the initial charge of the capacitor is gradually charged through the switch S1, the diode D1 of the X driver 101 and the inductor L, as shown in the section 1 of FIG. The voltage of the sustain pulse rises to V _s [V] due to the resonance phenomenon between the inductor L and the capacitor.

At this time, the switch S3 is closed to supply the V _s [V] voltage from the voltage power supply. Therefore, the waveform of the sustain pulse may be maintained in a constant DC state without ripples in the resonance state, as in section 2 of FIG. 2.

While the voltage is kept constant, gas discharge occurs in the cells of the panel and the display current is generated rapidly. However, the gas discharge ends soon and the voltage remains constant.

In order to discharge the charge charge of the panel capacitor Cp, the switches S2 and S6 are closed and the other switches are opened. Accordingly, the discharge current of the panel capacitor Cp charges the energy recovery capacitor Cs via the inductor L and the diode D2, and the voltage of the sustain pulse gradually decreases as shown in section 3 of FIG. Descends.

Finally, the switches S2 and S4 are closed so that residual energy, such as inductor L, is removed through ground. This series of operations are similarly repeated by the Y driver 2, so that the sustain pulse is applied to the panel capacitor Cp alternately through the X electrode and the Y electrode.

As described above with respect to the section 3 of FIG. 2, the reactive power used in the initial rising section of the sustain pulse is recovered to the energy recovery capacitor Cs through the discharge of the panel capacitor Cp. Power consumption is reduced by this energy recovery circuit, and power consumption is generated only by the display current.

The driving circuit of the conventional plasma display panel is simple in structure and good in recovery rate, but has a disadvantage in that it cannot recover or reduce power consumed for display. Since the plasma display panel consumes about 10 [W] per inch, the larger the panel, the greater the power consumption, which impedes the technical realization.

Accordingly, an object of the present invention is to provide a plasma display panel in which power consumption is reduced.

According to the present invention, a panel capacitor including a first discharge electrode and a second discharge electrode, a power connection switch for connecting the first discharge electrode to a power supply unit, and a first discharge electrode are connected to a ground terminal. A plasma display panel having a ground connection switch for connecting, comprising: a first switching unit for switching a connection between a power supply unit and a first discharge electrode and for switching a connection between the ground terminal and the first discharge electrode; A first capacitor connected in series between the power supply unit and the first discharge electrode by the first switching unit when the power connection switch is turned on; A second switching unit for switching a connection between the other end of the second capacitor and the second discharge electrode; When the power supply connection switch is turned on, the power supply unit and the first discharge electrode are connected, and when the ground connection switch is turned on, the first switching unit is controlled to be connected to the ground terminal and the first discharge electrode, and the power supply unit and the first discharge electrode are connected. It may be achieved by a plasma display panel comprising a switching control unit for controlling the second switching unit to connect the other end of the second capacitor and the second discharge electrode.

Herein, when the power switch and the ground connection switch are turned off, the first switch may further include an inductor connected to the first discharge electrode in series without passing through the first capacitor.

In addition, when the panel capacitor is discharged, when the power connection switch and the ground connection switch are turned off, the second discharge electrode is connected to the ground terminal via the second capacitor by setting of the second switching unit.

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

3 is a driving circuit diagram of a plasma display panel according to an embodiment of the present invention.

As shown in Fig. 3, the driving circuit has a panel capacitor Cp, an X driver 1 and a Y driver 2.

The driving circuit of FIG. 3 further includes a discharge current recovery capacitor Cg and switches S9 to S12 in the X driving unit 1 and the Y driving unit 2 as compared with the conventional driving circuit shown in FIG. There is a difference.

In the driving circuit of FIG. 3, like the conventional driving circuit, the panel capacitor Cp is a model of the discharge electrode as an equivalent capacitor, and the configuration and operation of the X driving unit 1 and the Y driving unit 2 are symmetrically. Matches.

FIG. 4 shows waveforms of sustain pulses applied to the X electrode shown in FIG. 3 and 4, the process of applying the sustain pulse to the X electrode will be described in detail together with the switching control process of the circuit.

[V]의 전압으로, 방전전류 회수용 캐패시터(Cg)는 V_a[V]의 전압으로 초기 충전되어 있다. First, the energy recovery capacitor Cs of the X driver 1

At a voltage of [V], the discharge current recovery capacitor Cg is initially charged at a voltage of V _a [V].

With all switches open, the switches S1, ground connection switch S6, S10 and S12 are closed.

Accordingly, the initial charge of the energy recovery capacitor Cs passes through the switch S1, the diode D1, the inductor L, and the switching S10, and as shown in section 1 of FIG. Slowly charge. The voltage of the sustain pulse rises to V _c [V] due to the resonance phenomenon between the inductor L and the capacitor.

At this time, the switches S1, S3, the ground connection switch S6, S9 and S11 are closed to supply the voltage of V _c [V] from the voltage power supply and the voltage of V _a [V] from the discharge current recovery capacitor Cg. do. Therefore, the waveform of the sustain pulse can be maintained in a constant DC state without ripples in the resonance state, as in section 2 of FIG. 4.

While the voltage is kept constant, gas discharge occurs in the cells of the panel and the display current is generated rapidly. The charge due to the display current is stored in the panel capacitor Cp, and the same charge is stored in the discharge current recovery capacitor Cg of the Y driver 2 connected in series.

At this time, the formed charge acts as part of the display current when the charging voltage is supplied from the next Y driver 2, thereby reducing the amount of current applied from the actual power supply. That is, when the maximum size of the sustain pulse is V _s [V], the voltage applied from the actual power supply is V _c [V] smaller than V _s [V], and the insufficient voltage or current is a discharge current recovery capacitor ( It is supplied from Cg) and power consumption is reduced. Since the electric energy is exchanged between the discharge current recovery capacitor Cg of the X driver 1 and the discharge current recovery capacitor Cg of the Y driver 2, the display current is supplemented, and thus the power consumption actually supplied from the voltage power supply. Will decrease.

In addition, since the load on the sustain pulse is a series connection circuit of the panel capacitor Cp and the discharge current recovery capacitor Cg of the Y driver 2, the total capacitance of the load is reduced and the display current is reduced. . Therefore, it can be seen that power consumption by the display current is also reduced. At this time, properly setting the capacitance of each capacitor is very important to ensure the normal operation of the circuit.

For example, if the capacitance of the discharge current recovery capacitor Cg is set smaller than that of the panel capacitor Cp, the charge to be charged becomes smaller and the voltage applied to the panel becomes smaller so that display discharge may not occur. have. Therefore, the capacitance of the discharge current recovery capacitor Cg is preferably set to several ten times larger than that of the panel capacitor. In this case, however, the degree to which the rise time of the holding pulse is delayed should be considered. When the capacitance of the discharge current recovery capacitor Cg is set to 10 times that of the panel capacitor Cp, the load capacitance decreases by about 10%.

Referring back to section 2 of FIG. 4, after that, the gas discharge ends soon and the state in which the voltage is kept constant continues.

Next, in order to discharge the charge charge of the panel capacitor Cp, the switches S2, the ground connection switch S6, S10 and S12 are closed and the other switches are opened. Accordingly, the discharge current of the panel capacitor Cp charges the energy recovery capacitor Cs via the inductor L and the diode D2, and the voltage of the sustain pulse is shown in section 3 of FIG. , Is slowly descending.

Finally, the switch S2, the ground connection switch S4 and S10 are closed so that residual energy such as the inductor L is removed through the ground. This series of operations are equally repeated by the Y driver 2. Therefore, the sustain capacitor is alternately applied to the panel capacitor Cp through the X electrode and the Y electrode.

Meanwhile, in section 2 of FIG. 4, the switch S12 may be turned on instead of the switch S11. In this case as well, while the voltage of the sustain pulse is kept constant, gas discharge occurs in the cells of the panel, and the display current is generated rapidly. However, the charge due to this display current is stored in the panel capacitor Cp.

Thereafter, in interval 3 of FIG. 4, the switch S11 may be turned on in place of the switch S12. Accordingly, the discharge current charges the discharge current recovery capacitor Cg of the Y drive unit 2 from the ground, and charges the energy recovery capacitor Cs of the X drive unit 1. Therefore, upon application of the sustain pulse from the next Y driver 2, the display current is supplied from the discharge current recovery capacitor Cg of the Y driver 2 to the panel capacitor Cp.

In this embodiment, each switch is implemented by a switching element such as a relay or a transistor. The turn on / off timing of each switching element may be accurately controlled through a switching controller (not shown) configured by a microcontroller or the like.

In addition, the discharge current recovery capacitors Cg of the X driving unit 1 and the Y driving unit 2 are connected in series during the charging of the panel capacitor Cp composed of the discharge electrode or the sustain electrode, thereby reducing the equivalent capacitance. . At this time, due to the reduction of the capacitance, the magnitude of the display current for emitting the cell can be reduced, thereby reducing the overall power consumption.

When discharging, the series connection is cut off, thereby increasing the equivalent capacitance. Here, it will be readily understood that connection of each capacitor is controlled by a switching unit including the switches S9 to S12 and the switching control unit in the above-described embodiment.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that the embodiments may be modified without departing from the spirit or spirit of the invention. . It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

According to the present invention, power consumption of the plasma display panel can be reduced.

Claims (3)

A panel capacitor comprising a first discharge electrode and a second discharge electrode, a power connection switch for connecting the first discharge electrode to a power supply, and a ground connection switch for connecting the first discharge electrode to a ground terminal In the plasma display panel, A first switching unit for switching the connection between the power supply unit and the first discharge electrode and for switching the connection between the ground terminal and the first discharge electrode; A first capacitor connected in series between the power supply unit and the first discharge electrode by the first switching unit when the power connection switch is turned on; A second switching unit for switching a connection between the other end of the second capacitor and the second discharge electrode; When the power connection switch is turned on, the power supply unit and the first discharge electrode is connected, and when the ground connection switch is turned on, the first switching unit is controlled to connect the ground terminal and the first discharge electrode, and the power supply unit And a switching controller configured to control the second switching unit so that the other end of the second capacitor and the second discharge electrode are connected when the first discharge electrode is connected. The method of claim 1, And when the power switch and the ground connection switch are turned off, the plasma display further includes an inductor connected to the first discharge electrode in series without passing through the first capacitor by the first switching unit. panel. The method of claim 2, When the panel capacitor is discharged, when the power connection switch and the ground connection switch are turned off, the second discharge electrode is connected to the ground terminal via the second capacitor by setting of the second switching unit. Plasma display panel.

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