KR100827596B1 - The flap type fluorescent lamp which has a temperature induction member - Google Patents

Abstract

The present invention relates to a flat fluorescent lamp having a temperature inducing member that can prevent the mercury in the flat fluorescent lamp constituting the backlight unit to concentrate on either side due to the temperature distribution unevenness in the channel. A typical configuration includes a plate-shaped lower plate 11, a plurality of channels 13 filled with mercury, and an upper plate 12 bonded to the lower plate and supplying power to generate light in the channel 13. Power is supplied to the electrode 14 and the electrode 14 to maintain a uniform temperature distribution of the channel 13 when the flat fluorescent lamp 10 is turned on, and induces a temperature attached to the bottom of the lower plate 11. The member 20 is included.

 Flat fluorescent lamp, channel, temperature distribution, temperature induction member, electrode

Description

The flap type fluorescent lamp which has a temperature induction member}

1 is a cross-sectional view showing a backlight unit in which a general flat fluorescent lamp is installed.

Figure 2 is a cross-sectional view taken along the line A ­ A in FIG.

Figure 3 is a plan view and a temperature distribution graph showing a typical flat fluorescent lamp.

Figure 4 is a perspective view of a flat fluorescent lamp according to the present invention.

5 is a cross-sectional view of a flat fluorescent lamp according to the present invention.

6 to 9 are a plan view and a temperature plot graph showing a flat fluorescent lamp according to the present invention.

※ Explanation of symbols about main part of drawing ※

10 flat plate fluorescent lamp 11 bottom plate

12: top plate 13: channel

14 electrode 20 temperature induction member

The present invention relates to a flat fluorescent lamp having a temperature inducing member, and more particularly, to a temperature inducing member which can prevent the mercury charged in the flat fluorescent lamp constituting the backlight unit from being concentrated on either side. The present invention relates to a flat fluorescent lamp provided.

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 displaying a character or an image in a 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 type 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 1 is composed of a lower plate 2 having a predetermined size and an upper plate 3 attached to an upper surface of the lower plate 2, as shown in FIGS. Channel 3 is formed to protrude upward so as to form a discharge space, phosphor is coated on the inner surface of channel 4, and mercury is filled in channel 4.

On the other hand, electrodes 5 for supplying power are provided at both ends of the channel 4 provided in the flat fluorescent lamp 1.

Therefore, when power is supplied to the electrode 5, light is generated in the flat fluorescent lamp 1.

Thus, when light is generated from the flat fluorescent lamp 1, the flat fluorescent lamp 1 is to be raised in temperature, the temperature distribution is the amount of the flat fluorescent lamp 1 as shown in FIG. The temperature of the end portion, that is, the portion where the electrode 5 is installed, rises rapidly, and the temperature distribution between the portion where the electrode is adjacent and the center portion is distributed in a curved shape in which the temperature of the center portion is high.

Therefore, the mercury charged in the flat fluorescent lamp 1 has a characteristic of concentrating to a low temperature. Therefore, as described above, the mercury filled in the flat fluorescent lamp 1 is separated from the electrode and concentrated to an adjacent part of the electrode. There was a problem that can not maintain the luminance uniformity of.

The present invention has been made in order to solve the above problems, the object is to install a temperature inducing member for adjusting the temperature on the bottom surface of the flat fluorescent lamp is installed inside the body of the backlight unit to generate light the flat fluorescent lamp It is to provide a flat fluorescent lamp having a temperature inducing member that can prevent the mercury charged in any portion concentrated.

Referring to the characteristic configuration of the present invention for achieving the above object is as follows.

The flat fluorescent lamp of the present invention includes a plate-shaped lower plate, an upper plate having a plurality of channels bonded to the lower plate and filled with mercury, an electrode for supplying power to the channel, and a uniform temperature distribution in the channel. And a temperature inducing member.

Referring to the present invention having such characteristics in detail as follows.

Figure 4 is a perspective view showing a flat fluorescent lamp according to the present invention, Figure 5 is a cross-sectional view of a flat fluorescent lamp according to the present invention, Figures 6 to 9 are a plan view and a temperature showing a flat fluorescent lamp according to the present invention The plot graph.

As referred to herein, in the present invention, a plate-shaped lower plate 11 having a predetermined size is provided, and an upper plate 12 is attached to an upper surface of the lower plate 11, and a plurality of upper plates 12 are provided. The channel 13 is formed to protrude upwards, and mercury is filled in the channel 13.

Electrodes 14 for supplying power are provided at both ends of the channel 13.

As described above, the bottom surface of the flat fluorescent lamp 10 including the lower plate 11, the upper plate 12, and the electrode 14 may maintain the temperature distribution of the channel 13 uniformly. Is installed, the temperature induction member 20 is made of silicon.

 Therefore, when power is applied to the electrode 14, light is generated in the channel 13, and the temperature distribution of the flat fluorescent lamp 10 in which the temperature inducing member 20 is installed on the bottom surface of the electrode 14. Is as shown in Figure 6,

As referred to herein, the temperature at both ends of the channel 13 provided with the electrode 14 is lowered by the temperature inducing member 20 installed at the bottom thereof, so that mercury charged in the channel 13 is partially moved. Concentration is prevented.

On the other hand, the temperature distribution of the flat fluorescent lamp 10 in which the temperature inducing member 20 is installed at the bottom of the electrode 14 and the center of the bottom of the lower plate 11 is a channel in which the electrode 14 is installed. Both ends of the (13), as well as the central portion of the channel 13 is lowered in the temperature induction member (20).

That is, since both ends of the channel in which the electrode 14 is installed, the temperature rises rapidly and the non-uniform temperature distribution occurs due to the heat generation of the electrode, the first temperature induction member (temperature induction member for maintaining a constant temperature distribution of the electrode ) Is installed on the bottom of the lower plate. The first temperature inducing member may be a silicon pad. The first temperature inducing member lowers the temperature of the high temperature part among the temperature of the electrode part and moves the heat to the low temperature part of the relatively low temperature to maintain a uniform temperature as a whole.

In addition, the second temperature induction member (temperature induction member for maintaining a constant temperature distribution in the center portion of the channel) provided in the center portion of the panel makes the non-uniform temperature distribution uniform inside the panel. That is, inside the panel, the temperature of the center is higher than the temperature of the adjacent part of the center due to the heat generated by the driving chips installed behind the panel and the convection generated in the entire panel. . Therefore, the mercury in the high temperature is moved to the low temperature portion, reducing the overall brightness uniformity. Therefore, the second temperature inducing member of the present invention is installed in a high temperature part in the panel to lower the temperature to prevent the separation of mercury, thereby achieving a uniform brightness throughout the panel.

On the other hand, the temperature inducing member 20, as shown in Figure 8 may be further installed on both sides, as well as the bottom center portion of the lower plate (11).

When the temperature induction member 20 is installed on both sides as described above, the temperature of the channel 13 is lowered by the temperature induction members 20, thereby reducing the temperature deviation generated in the channel 13. .

In addition, the temperature induction member 20 may be provided in plural on both sides of the center as shown in Figure 9, in this case, the width of the temperature induction member 20 installed in the center is formed wide, the electrode It is preferable that the width of the temperature induction member 20 proximate to the side of (14) be formed to be gradually narrowed.

As referred to herein, the temperature deviation of the channel 13 is reduced.

As described above, the present invention reduces the temperature of the channel by the temperature induction members installed at both sides of the bottom plate as well as the center of the bottom plate, thereby preventing the concentration of mercury from being concentrated. There is a special effect.

In addition, the present invention has a unique effect of improving the uniformity of the brightness of the flat fluorescent lamp because the mercury charged in the channel does not concentrate to any part.

Claims (6)

Plate-shaped lower plate 11; An upper plate 12 bonded to the lower plate 11 and having a plurality of channels 13 disposed in parallel to each other; Electrodes 14 provided at both ends of the channel 13 in the longitudinal direction; A plurality of first temperature inducing members attached to the bottom surface of the lower plate 11 of the electrode 14 arrangement portion; And And a second temperature inducing member attached to a bottom surface of the lower plate 11 between both ends of the channel 13. According to claim 1, wherein the second temperature inducing member is a flat plate having a temperature inducing member, characterized in that a plurality is attached to the bottom surface of the lower plate 11 to be arranged in a direction perpendicular to the longitudinal direction of the channels (13). Type fluorescent lamp. 3. The flat fluorescent lamp of claim 2, wherein any one of the plurality of second temperature inducing members is attached to the center of the channel in the longitudinal direction. 4. The temperature of claim 3, wherein the second temperature inducing member attached to the longitudinal center of the channels 13 is wider in width than the second temperature inducing member attached in close proximity to the first temperature inducing member. Flat fluorescent lamp having an induction member. 5. The flat fluorescent lamp of claim 4, wherein the first and second temperature inducing members are made of silicon. 3. The flat fluorescent lamp of claim 2, wherein the plurality of second temperature inducing members are attached to be symmetrical about a longitudinal center of the channel (13).

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