KR100794568B1 - The flat type fluorescent lamp - Google Patents

Abstract

The present invention relates to a planar fluorescent lamp in which a thin film type cooling member is installed in the planar fluorescent lamp so that mercury charged in the lamp can be uniformly distributed in each channel regardless of the uneven temperature distribution present in the fluorescent lamp. .

The technical constitution of the present invention for achieving the above object is a second substrate having a flat plate-shaped first substrate 11 and a plurality of channels 13 bonded to the first substrate 11 and filled with mercury. A flat fluorescent lamp comprising a substrate 12, a central passage 14 formed to connect the center of each channel 13, and electrodes 15 provided at both ends of the channel 13 to supply power. In this case, the thin film type cooling member 20 is installed on the bottom surface of the first substrate 11 and is disposed between the electrodes 15 provided at both ends of the channel 13.

Description

The flat type fluorescent lamp

1 is a perspective view showing the structure of a conventional flat fluorescent lamp.

2 is a plan view showing a non-uniform temperature distribution of a conventional flat fluorescent lamp.

Figure 3 is a perspective view showing an embodiment of a flat fluorescent lamp according to the present invention.

4 to 8 are views showing various embodiments of the thin-film cooling member according to the present invention.

※ Explanation of symbols about main part of drawing ※

10: flat fluorescent lamp 11: first substrate

12: second substrate 13: channel

14: central passage 15: electrode

20: thin film type cooling member 21: thin film type housing

22: thin film

The present invention relates to a flat fluorescent lamp, and more particularly, by installing a thin-film cooling member on the flat fluorescent lamp, mercury charged in the lamp is uniformly uniform in each channel regardless of the uneven temperature distribution present in the fluorescent lamp. The present invention relates to a flat fluorescent lamp that allows for distribution.

Liquid Crystal Display (LCD) (hereinafter referred to as "LCD") used as a display device causes less eye fatigue than conventional CRT display devices, and can be made compact, lightweight, and low power. As a next generation display device of a mobile phone or a television, it is very popular and products of various sizes are being developed.

Referring to the structure of the LCD panel for displaying a character or an image in the conventionally used LCD as follows. When a liquid crystal material is injected between a pair of surface-treated transparent glass plates, and an electric signal (voltage) is supplied by using an LCD controller which generates a driving signal to the injected liquid crystal material, a phase change of the liquid crystal material is generated accordingly.

The LCD driving circuit can display specific characters or images by giving different voltage values according to the distribution of the liquid crystal material.

However, in LCD, since the panel on which the characters are displayed does not shine by itself, a means of assisting visual recognition of the contents (characters, images, logos, etc.) displayed on the panels is required. Currently, a back light system using a lamp for irradiating light from the side or the back of the liquid crystal panel is widely used as an auxiliary means.

Conventionally used backlight systems are classified into an edge type backlight and a direct type backlight according to the position of a lamp for projecting light. An edge type backlight is a method in which light sources are positioned below both sides of a panel so that light incident from the light source generates a surface light source by a light guide plate and a reflecting plate to illuminate a cell of an LCD panel. Such an edge method has an advantage of high luminance uniformity because it indirectly induces light emitted from a light source, but on the other hand, there is a problem that the luminance is relatively low.

In addition, the direct backlight has a light source located directly below the LCD panel, and a diffuser plate is disposed on the front surface of the light source, and a reflector plate is disposed on the rear surface to reflect and diffuse the light emitted from the light source, thereby dimming the cells of the LCD panel. to be. Since the direct method uses light efficiently by using a reflecting plate and a diffusion plate, high brightness can be obtained, and therefore, it is suitable for backlights requiring high brightness.

However, there is a limit in providing sufficient luminance according to the size of the LCD panel which is gradually becoming larger, and there is a problem that the luminance uniformity is lowered.

As a solution to this problem, flat fluorescent lamps have recently been used.

The flat fluorescent lamp 10 is composed of a first substrate 11 having a predetermined size and a second substrate 12 bonded to the upper surface of the first substrate 11, as shown in FIG. In addition, the second substrate 12 has channels 13 formed at regular intervals so as to protrude upward to form a discharge space. Phosphor is applied to the inner surface of the channel 13, and mercury is filled in the channel 13.

In addition, a central passage 14 connecting adjacent channels 13 is formed at the central portion of each channel 13. This central passage 14 allows mercury to diffuse between each channel 13.

On the other hand, electrodes 15 for supplying power are provided at both ends of the channel 13 provided in the flat fluorescent lamp 10. Therefore, when power is supplied to the electrode 15, light is generated from the flat fluorescent lamp 10.

When the light is generated in the flat fluorescent lamp 10 as described above, the flat fluorescent lamp 10 is raised in temperature, and the temperature distribution is flat fluorescent in the horizontal X-axis direction as shown in FIG. The temperature of both ends of the lamp 10, that is, the portion A in which the electrode 15 is installed, rises sharply, and the temperature of the central portion B of the lamp in which discharge is mainly generated is increased between the portion A and the lamp in which the electrode is installed. It is distributed in a curved shape that appears higher than between the central portion B of and draws three peaks as a whole.

On the other hand, when looking at the temperature distribution in the vertical Y-axis direction, both edge portions C tend to radiate heat more easily around the center portion B than the central portion B of the flat fluorescent lamp 10, and thus exhibit a lower temperature. It is distributed in a curved shape drawing two peaks.

Since the above temperature distribution has been experimented with only the flat fluorescent lamp 10, when the flat fluorescent lamp 10 is installed in the LCD panel, it has a different shape from that of FIG. It has a temperature distribution, whereby the temperature becomes more uneven.

As such, when the temperature is unevenly distributed in the flat fluorescent lamp 10, the distribution of mercury in each channel 13 is also uneven due to the characteristic of mercury that collects at a low temperature. As a result, various problems have occurred such that the luminance uniformity of the lamp is not maintained and a pink phenomenon in which the mercury is scarce at the initial stage of discharge occurs.

The present invention has been proposed to solve this problem, by providing a thin film type cooling member at a predetermined position of the flat fluorescent lamp to effectively maintain the brightness uniformity of the lamp irrespective of the uneven distribution of temperature generated inside the lamp. The purpose is to provide a flat fluorescent lamp.

According to an aspect of the present invention, there is provided a flat fluorescent lamp comprising: a flat substrate-shaped first substrate, a second substrate having a plurality of channels bonded to the first substrate and filled with mercury; In the flat fluorescent lamp consisting of a central passage formed to connect the center and the electrodes provided at both ends of the channel for supplying power, a thin film type cooling member is installed on the bottom surface of the first substrate, both ends of the channel It is installed to be located between the electrodes installed in.

Hereinafter, a technical configuration of a flat fluorescent lamp according to the present invention will be described in detail with reference to the accompanying drawings.

3 to 5 show one exemplary embodiment of a flat fluorescent lamp according to the present invention. For the sake of understanding, the same components as those of the flat fluorescent lamp 10 are denoted by the same reference numerals as in FIG. Also in the present invention, the basic configuration of the flat fluorescent lamp 10 is the same as in the related art. In brief, the first substrate 11 having a predetermined size and the upper surface of the first substrate 11 are bonded to the inside of the mercury. The filled channel 13 is formed of a second substrate 12 formed at regular intervals, and a central passage 14 is formed at a central portion of each channel 13, and at both ends of the channel 13. An electrode 15 for supplying power is provided.

A characteristic technical configuration of the present invention is to install the thin film type cooling member 20 on the bottom surface of the first substrate 11 at a predetermined position so as to control the distribution of mercury charged in the channel 13.

The thin film type cooling member 20 is made of a material having high thermal conductivity, such as aluminum and silicon, and is manufactured in a thin film form in order to increase a heat radiation effect. Since the thin film type cooling member 20 functions to collect mercury by lowering the temperature in the channel 13 at the installed position, the installation position is important.

When the thin film type cooling member 20 is installed at both ends ("D" position in FIG. 3) of the channel 13 in which the electrode 15 is installed, mercury is concentrated there, and thus diffuses into the center of the channel 13, which is a discharge space. Since it takes a long time, not only the initial start-up time is delayed, but the uniformity of luminance is also reduced.

Therefore, the thin film type cooling member 20 is preferably installed on the bottom surface of the first substrate 11 and is disposed between the electrodes 15 provided at both ends of the channel 13. For example, when the thin film type cooling member 20 is installed at the center ("E" position in FIG. 3) of the channel 13 in which the connection passage 14 is formed, the central portion of the channel 13 where most of the mercury is a discharge space is provided. As a result, the diffusion time is short, so that discharge is easily performed, and luminance uniformity is also maintained.

Most preferably, the thin-film cooling member 20 is installed so as to be positioned between the central passage 14 and the electrode 15 ("F" position in Figure 3). When the thin film type cooling member 20 is provided between the central passage 14 and the electrode 15 in both directions, mercury is evenly distributed over the entire discharge space of the channel 13, so that uniformity of luminance is further increased.

In order to achieve the effect of the present invention, the shape of the thin-film cooling member 20 is also important. In the thin film type cooling member 20, in order to increase the heat dissipation effect, the thin film material 22 bent in a wave shape as shown in FIG. 4 (a) or (b) is perpendicular to the longitudinal direction of the channel 13 (X). -X '). In this case, the thin film member 22 may extend in a wave shape of the thin film material 22 perpendicular to the XX 'direction as shown in FIG. 3 (a), or as shown in FIG. 4 (b). The wave shape of 22) may extend parallel to the XX 'direction.

In the case of FIG. 4A, since the wavy thin film material 22 is repeated in the XX 'direction, the wavy thin film material 22 is overlapped in a direction perpendicular to the bottom surface of the first substrate 11, which is a direction in which heat in the channel 13 is discharged. While the portion is small, the heat dissipation effect is high, while the portion in contact with the bottom surface of the first substrate 11 is small, and the adhesion force is lowered. On the contrary, in the case of FIG. 4B, since the wavy thin film material 22 overlaps in the direction in which heat in the channel 13 is discharged, the heat dissipation effect is relatively low while the first substrate 11 The adhesion is high because it is in contact with the bottom and a large area. In consideration of this point, the shape of the thin film material 22 can be selected according to the specification of the product.

Meanwhile, as shown in FIG. 5, the thin film type cooling member 20 surrounds the thin film member 22 that is bent in a wavy manner with the thin film type housing 21 directly bonded to the bottom surface of the first substrate 11. It may be installed. The thin-film housing 21 may be installed in a box shape as shown in FIG. 3, and may be installed to surround only the upper and lower portions of the thin film material 22 by forming a plate. The shape of the thin-film housing 21 is selected in consideration of the specifications of the product, the heat dissipation effect, the adhesion.

As shown in FIG. 6, the wavy thin film cooling member 20 may be provided in two or more layers in order to increase the cooling effect. FIG. 6 illustrates a form in which the thin film housing 21 is installed together, but according to the present invention, only the thin film material 22 may be installed to be attached in multiple layers.

7 and 8 illustrate various embodiments of the shape of the thin-film cooling member 20. According to FIG. 7, the thin film type cooling member 20 is installed in such a manner that a plurality of thin film materials 22 in a plate form cross each other, and extend in a direction perpendicular to the longitudinal direction of the channel 13. . The thin film material 22 in the form of a plate may be in the form of horizontally and vertically intersecting as shown in FIG.

According to FIG. 8, the thin film type cooling member 20 has a tube shape extending in a direction perpendicular to the longitudinal direction of the channel 13, and a plurality of thin film materials 22 having a circular or polygonal cross section are attached to each other. It may be installed as. FIG. 8A illustrates a case in which the cross section is circular, and FIG. 8B illustrates a case in which the cross section is hexagonal. However, the present invention is not limited thereto.

7 and 8 illustrate a thin film housing 21 directly bonded to the bottom surface of the first substrate 11 so as to surround the thin film material 22 in the form of a plate or a tube, but the thin film housing ( 21 may be installed directly in the form of a plate or tube 22.

As described above, since the thin film type cooling member 20 according to the present invention may be made in various forms in consideration of the heat dissipation effect and the adhesive force, the technical idea of the present invention is not limited to the above embodiment, If so, all other embodiments will be included in the technical scope of the present invention.

As described above, according to the flat fluorescent lamp of the present invention, the uniformity of luminance can be improved by allowing the mercury to be uniformly distributed regardless of the temperature distribution in the lamp. In addition, mercury in the channel is prevented from occurring, which prevents pink from occurring early in the discharge.

Claims (8)

A second substrate 12 having a flat plate-shaped first substrate 11, a plurality of channels 13 bonded to the first substrate 11 and filled with mercury, and a center of each of the channels 13 In the flat fluorescent lamp consisting of a central passage 14 formed to connect and the electrode 15 provided at both ends of the channel 13 to supply power, Flat-film fluorescent lamp is installed on the bottom surface of the first substrate (11), the thin film type cooling member is located between the electrodes (15) installed at both ends of the channel (13). The planar fluorescent lamp of claim 1, wherein the thin film type cooling member 20 is installed such that the thin film material 22 bent in a wave shape extends in a direction perpendicular to the longitudinal direction of the channel 13. . The flat fluorescent lamp of claim 2, wherein the wave shape of the thin film material (22) is formed to extend horizontally or vertically in a direction perpendicular to the longitudinal direction of the channel (13). 3. The flat fluorescent lamp of claim 2, wherein two or more wavy thin film materials are provided in multiple layers. The thin film cooling member of claim 2, wherein the thin film cooling member 20 is a thin film material in which the thin film housing 21 directly bonded to the bottom surface of the first substrate 11 is bent in a wavy shape. 22) A flat fluorescent lamp, characterized in that installed to surround. According to claim 1, wherein the thin-film cooling member 20 is installed in the form of a plurality of thin film material 22 in the form of cross each other, so as to extend in a direction perpendicular to the longitudinal direction of the channel (13) Flat fluorescent lamps, characterized in that installed. According to claim 1, wherein the thin-film cooling member 20 has a tubular shape extending in a direction perpendicular to the longitudinal direction of the channel 13 and a plurality of thin film members 22 having a circular or polygonal cross section is attached to each other. Flat fluorescent lamp, characterized in that installed in the form. According to claim 6 or 7, wherein the thin-film cooling member 20 is characterized in that the thin-film housing 21 which is directly bonded to the bottom surface of the first substrate 11 is installed so as to surround the thin film material (22). Flat fluorescent lamps.

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