KR100736778B1 - Structure of electrode in flat luminescence lamp - Google Patents

Abstract

The present invention relates to an electrode structure of a surface emitting lamp that can improve the light efficiency of the lamp by preventing discharge in the non-discharge space.

In order to achieve the above object, the present invention is a top plate formed with a plurality of channels protruding at regular intervals so that the phosphor is coated on the inner surface and the discharge gas is filled, the bottom surface of the top plate is sealed to form a discharge space inside the channel A surface light emitting lamp comprising a lower plate and an upper electrode disposed on an upper plate so as to be positioned at both ends of the channel, and a lower electrode disposed on the lower plate so as to correspond to each other, wherein the upper electrode is an end portion of the channel that is a portion that actually contributes to discharge. It consists of an effective electrode installed on the surface.

Surface emitting lamp, upper electrode, lower electrode, effective electrode, connecting electrode,

Description

Structure of electrode in flat luminescence lamp

1 is a perspective view of an electrode structure of a conventional surface light emitting lamp.

Figure 2 is a cross-sectional view taken along the line AA 'of Figure 1;

3 is a cross-sectional view taken along the line BB 'of FIG. 1;

4 is a perspective view of one embodiment according to the present invention;

5A and 5B are sectional views taken along the line C-C 'in Fig. 4;

Figure 6 is a perspective view of another embodiment according to the present invention.

7 is a partial plan view of FIG. 6;

※ Explanation of symbols about main part of drawing ※

11: surface emitting lamp 12: top plate

13: channel 14: bottom plate

15: discharge space 16: upper electrode

17a: effective electrode 17b: connecting electrode

18: lower electrode

The present invention relates to an electrode structure of a surface light emitting lamp, and more particularly, to a surface light emitting lamp comprising a top plate having a plurality of channels and a bottom plate sealed on a bottom thereof, and having a predetermined discharge space formed therein. The light efficiency of the surface light emitting lamp is improved by changing the structure of the electrodes provided at both ends.

Generally, display apparatuses are classified into light emitting and light receiving types. Light emitting types include cathode ray tubes, electron light emitting devices, plasma display panels (PDPs), organic EL displays (OLEDs), and light receiving types. There is). The liquid crystal display itself does not have a structure that emits light and thus cannot visualize an image unless external light is irradiated. Accordingly, a separate light source, for example, a back light source device (Back light) should be installed so that the image can be viewed. The back light source device includes a method of diffusing light emitted from a cold cathode fluorescent lamp (CCFL) using a light guide plate and a diffusion plate, and a surface light emitting lamp (Flat) that excites phosphors by ultraviolet rays to emit visible light. luminescence lamp (FLL) method is used.

1 to 3, an example of a conventional surface light emitting lamp will be briefly described. The surface emitting lamp 1 includes a top plate 2 provided with a plurality of channels 3 protruding upward to form a discharge space 5 into which discharge gases such as xenon and neon are filled. The lower plate 4 is sealed to the lower surface of the upper plate 2 via a sealing member to prevent the discharge gas from leaking out, and is applied to both ends of the upper plate 2 and the lower plate 4 by an applied voltage. It consists of an upper electrode 6 and a lower electrode 8 which induce a gas discharge in the discharge space 5. Although not shown, phosphors emitting visible light are coated on the inner surface of the upper plate 2 to the lower plate 4 constituting the discharge space.

In the surface light emitting lamp 1 configured as described above, when an alternating current or pulse waveform voltage is applied to the electrodes 6 and 8 provided at both ends of the channel 3, the image and the electrode contacting the electrodes 6 and 8 An electric field is formed on the surfaces of the lower plates 2 and 4. The formed electric field accelerates the space charge in the discharge space, and the accelerated free electrons ionize the discharge gas to form a plasma state by increasing the number of space charges exponentially. The heat generated by the plasma promotes ionization of the discharge gas, and receives ultraviolet energy of space charge in the plasma state to stabilize the atoms of the excited discharge gas, thereby generating ultraviolet rays. This ultraviolet light excites the phosphors and emits visible light necessary for surface emission.

The conventional surface emitting lamp 1 has the following problems in the discharge process due to its electrode structure. As shown in FIG. 1, the upper electrode 6 is in contact with the surface of the channel 3 forming the discharge space 5, and the effective electrode 7a which actually contributes to the discharge when a voltage is applied, and the upper plate 2 in addition. And a support electrode 7b which contacts the surface corresponding to the bonding surface of the lower plate 4 and simply increases the contact area between the upper electrode 6 and the upper plate 2. Here, the discharge generated by the effective electrode 7a generates space charge in the discharge space 5, but the discharge generated by the support electrode 7b is not the discharge space 5 as shown in FIG. This is a problem because it occurs on the joint surface A of the upper plate 2 and the lower plate 4.

That is, the discharge by the supporting electrode 7b is a point (hereinafter referred to as "P1 point") and the channel 3 between the end of the effective electrode 7a and the end of the upper plate 2, which are non-discharge spaces, as shown in FIG. ) And a discharge between the lower electrode 8 also occurs at a point between the channel 3 and the channel 3 (hereinafter referred to as "P2 point"). The discharge in the non-discharge space consumes the voltage applied to the electrode, thereby lowering the discharge efficiency in the actual discharge space 5, thereby lowering the light efficiency of the entire surface light emitting lamp 1.

In addition, the high heat generated due to the discharge in the non-discharge space melts the sealing member used to seal the joint surface of the upper plate 2 and the lower plate 4, thereby lowering its adhesion. As a result, the discharge gas charged in the discharge space 5 leaks between the upper plate 2 and the lower plate 4 to lower the light efficiency. In severe cases, the lamp itself is damaged due to the high voltage applied to the non-discharge space. There is also a problem of shortening the life.

The present invention has been proposed to solve the above problems, and by improving the efficiency of the lamp by preventing the discharge in the non-discharge space by configuring the upper electrode installed on the top plate of the surface light emitting lamp only the effective electrode that actually discharges Its purpose is to provide an electrode structure of a surface emitting lamp.

In addition, another object of the present invention is to provide an electrode structure of a surface light emitting lamp in which a connection electrode is provided between the effective electrodes on the upper electrode so that a voltage can be applied to all the upper electrodes with one inverter.

The electrode structure of the surface light emitting lamp according to the present invention for achieving the above object is a top plate formed with a plurality of channels protruding at regular intervals so that the phosphor is coated on the inner surface and the discharge gas is filled, the bottom plate of the top plate is sealed to the channel In a surface emitting lamp comprising a lower plate forming a discharge space inside the upper plate, and an upper electrode disposed on the upper plate so as to be positioned at both ends of the channel, and a lower electrode disposed on the lower plate so as to correspond to the upper electrode, the upper electrode actually contributes to the discharge. And an effective electrode provided on both end surfaces of the channel.

In addition, the lower electrode is installed such that its outer end is located on the same vertical line as the outer end of the effective electrode.

In addition, the upper electrode may further include a connection electrode provided at a connection portion of an adjacent channel to connect the plurality of the effective electrodes, the width of the connection electrode is preferably less than 1/2 of the width of the effective electrode.

Hereinafter, an embodiment of an electrode structure of a surface light emitting lamp according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a perspective view of the present invention, Figures 5a and 5b is a cross-sectional view of the C-C 'direction. In the present invention, the surface light emitting lamp 11 has a top plate 12 having a plurality of channels 13 protruding at regular intervals so that phosphors are coated on the inner surface and filled with discharge gas, and a sealing member is disposed on the bottom surface of the top plate 12. A lower plate 14 sealed to form a discharge space 15 in the channel 13, and an upper electrode 16 provided on the upper plate 12 so as to be positioned at both ends of the channel 13, and correspondingly to the upper plate 16. It consists of a lower electrode 18 installed on the lower plate 12, which is the same as the conventional surface-emitting lamp described above.

The technical feature of the present invention lies in the configuration of the upper electrode. Conventionally, as shown in FIG. 1, the upper electrode 6 consists of an effective electrode 7a that actually contributes to discharge and a supporting electrode 7b that simply increases the contact area between the upper electrode 6 and the upper plate 2. As shown in FIG. 4, the present inventors pay attention to the fact that the light efficiency of the entire lamp is lowered due to the support electrode 7b. As shown in FIG. 4, the effective electrode 17a is a part that actually contributes to the discharge. It was made of bay. In other words, the upper electrode 16 according to the present invention is provided only on both ends of the channel 13.

According to the electrode structure of the present invention configured as described above, as shown in Fig. 4, since the upper electrode 6 does not exist at the P1 and P2 points where unnecessary discharge has conventionally occurred, discharge in the non-discharge space is prevented. However, if the lower electrode 18 is installed in the same size as the prior art, although the upper electrode 16 does not exist on the surface of the upper plate 12 corresponding to the P1 point, the surface of the lower plate 14 corresponding to the P1 point Since the lower electrode 18 is present in the same manner as in the related art, a discharge occurs between the effective electrode 17a and the lower electrode 18 provided on both ends of the channel 13, as shown in FIG. The bonding surface of the underplate 14 may be damaged.

Therefore, in order to completely prevent the discharge at the point P1, it is preferable to install the lower electrode 18 such that the outer end 18a is positioned on the same vertical line as both ends of the channel 13, as shown in FIG. 5B. .

According to another embodiment of the present invention, as shown in Figure 6, the upper electrode 16 is formed of the adjacent channel 13 to allow the effective electrodes 17a provided on both ends of the plurality of channels 13 to conduct with each other. The connection electrode 17b is installed at the connection site. Because, as shown in Figure 4, when the upper electrode 16 is independently separated for each channel 13, a separate inverter must be installed for each upper electrode 16 to apply a voltage, the circuit is complicated and the lamp This is because the weight of the whole increases.

Therefore, the connecting electrode 17b is provided at the connection portion of each channel 13 protruding at a predetermined interval so that the effective electrodes 17a are connected to each other, thereby applying the necessary voltage to all the effective electrodes 17a as one inverter. It is desirable to be able to reduce the weight of the entire lamp and simplify the circuit. The connection electrode 17b may be integrally formed with the effective electrode 17a.

However, since the portion where the connection electrode 17b is installed is the P2 point corresponding to the non-discharge space as shown in FIG. 6, when the connection electrode 17b is installed with the same width as the effective electrode 17a, the lamp may be discharged due to unnecessary discharge. The problem that the light efficiency is lowered still occurs. Therefore, as shown in FIG. 7, it is necessary to adjust the width t of the connection electrode 17b based on the width T of the effective electrode 17a. Here, the width t of the connecting electrode 17a is a width at which both ends are wrapped between the channels, and the width T of the effective electrode 17a is a width at which both ends of the channel are wrapped. The reference is the same direction as the longitudinal direction of the channel 13.

The inventors tested the effect of the discharge at the point P2 on the light efficiency of the entire lamp by varying the width t of the connecting electrode 17b in various ways. Since it is narrow and does not have a large influence on the light efficiency of the entire lamp, an unnecessary discharge at the point P2 will not occur unless the width t of the connecting electrode 17b exceeds only half the width T of the effective electrode 17a. It was found that it did not significantly affect the light efficiency of the entire lamp. Therefore, the maximum value of the width t of the connection electrode 17b is preferably set to 1/2 of the width T of the effective electrode 17a.

On the other hand, the smaller the width t of the connecting electrode 17b is advantageous in that the smaller the area where unnecessary discharge occurs, the smaller the width t is. However, if the width t of the connecting electrode 17b is too small, the resistance increases to increase the voltage. Because it becomes an obstacle to apply, it cannot be small. Furthermore, since the minimum value of the width t of the connection electrode 17b varies depending on the size of the surface light emitting lamp 11 and the intensity of the voltage applied thereto, the minimum value of the width t of the connection electrode 17b may be uniformly defined based on the width of the entire effective electrode 17a. Can't. Therefore, the width t of the connection electrode 17b may be limited to only 1/2 or less of the width T of the effective electrode 17a.

In summary, the electrode structure of the surface light emitting lamp according to the present invention comprises a non-discharge space by configuring the upper electrode 16 only on the effective electrodes 17a positioned on both ends of the channel 13 to actually contribute to the discharge. While preventing unnecessary discharge occurring on the junction surface of the upper plate 12 and the lower plate 14 of the phosphorescent light emitting lamp 11, the width T of the effective electrode 17a at the connection site of each channel 13 is prevented. It is a characteristic technical configuration that a voltage is applied to all the effective electrodes 17a with only one inverter by installing a connection electrode 17b having a width of 1/2 or less.

As described above, according to the electrode structure of the present invention, high brightness can be exhibited by preventing unnecessary discharge occurring on the bonding surface of the upper plate and the lower plate of the surface light emitting lamp to improve the light efficiency of the lamp. In addition, the life of the lamp can be improved by preventing damage to the lamp due to unnecessary discharge.

Claims (4)

A top plate 12 having a plurality of channels 13 protruding at regular intervals so that phosphors are coated on the inner surface and filled with discharge gas, and sealed on the bottom surface of the top plate 12 to discharge space 15 inside the channel 13. A lower plate 14 forming a lower surface, and an upper electrode 16 provided on the upper plate 12 so as to be positioned at both ends of the channel 13 and a lower electrode 18 provided on the lower plate 14 so as to correspond thereto. In the light emitting lamp, The electrode structure of the surface light emitting lamp, characterized in that the upper electrode (16) consists of effective electrodes (17a) provided on both end surfaces of the channel (13), which actually contribute to the discharge. 2. The surface of claim 1, wherein the lower electrode 18 is installed so that its outer ends are located on the same vertical line as the outer ends of the effective electrode 17a so as to be installed on both end surfaces of the channel. Electrode structure of luminescent lamp. 3. The upper electrode (16) according to claim 1 or 2, wherein the upper electrode (16) further comprises a connecting electrode (17b) provided at a connecting portion between adjacent channels (13) for connecting the plurality of effective electrodes (17a). An electrode structure of a surface emitting lamp. The method of claim 3, wherein the connection electrode 17b has a width t in the same direction as the channel 13 is less than or equal to 1/2 of the width T of the effective electrode 17a in the same direction as the channel 13. An electrode structure of a surface emitting lamp.

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