KR100827599B1 - The back light equipment which uses the flat fluorescent lamp - Google Patents

Abstract

A backlight light device using a flat fluorescent lamp is provided to enable power supply terminals, for supplying power to a surface electrode and a back electrode of a channel formed in the flat fluorescent lamp, to supply power in a state of being closely contacted by applied pressure, thereby preventing damage of the surface and back electrodes. A flat fluorescent lamp(100) is formed by attaching first and second substrates(110,120). A surface electrode(141) is formed in an edge of the first substrate. A back electrode(142) is formed in an edge of the second substrate. An upper cover(300) surrounds an upper part of the flat fluorescent lamp. A lower cover(200) surrounds a lower part of the flat fluorescent lamp. An upper support(310) is disposed between the upper cover and the flat fluorescent lamp to support the flat fluorescent lamp. A lower support(210) is disposed between the lower cover and the flat fluorescent lamp to support the flat fluorescent lamp. A first power supply terminal is inserted between the upper support and the surface electrode. In one end of the first power supply terminal, a first contact protrusion is formed. In the other end, a first connection hole is formed. A second power supply terminal is inserted between the lower support and the back electrode. In one end of the second power supply terminal, a second contact protrusion is formed. In the other end, a second connection hole is formed.

Description

BACK LIGHT EQUIPMENT WHICH USES THE FLAT FLUORESCENT LAMP}

1 is an exploded perspective view showing a conventional flat fluorescent lamp.

2 is a cross-sectional view showing a conventional flat fluorescent lamp.

3 is a cross-sectional view showing a conventional backlight device.

4 is a cross-sectional view showing a backlight device according to the present invention;

Figure 5 is an exploded perspective view showing a power supply terminal of the backlight device according to the present invention.

6 to 9 are perspective views showing another embodiment of a power supply terminal for a backlight device according to the present invention.

※ Explanation of symbols about main part of drawing ※

100: flat fluorescent lamp 110: first substrate

111: channel 120: second substrate

141: surface electrode 142: back electrode

200: lower cover 201: receiving groove

202: lower pressing projection 210: lower support

300: upper cover 301: display hole

302: upper pressing projection 310: upper support

400: LCD module 500: power supply line

600, 600a, 600b, 600c, 600d: first power supply terminal

610, 610a, 610b, 610c, 610d: first connection port

611, 611a, 611b, 611c, 611d: first contact protrusion

700, 700a, 700b, 700c, 700d: second power supply terminal

710, 710a, 710b, 710c, 710d: second connection port

711, 711a, 711b, 711c, 711d: second contact protrusion

The present invention relates to a planar fluorescent lamp, and more particularly, to a power supply terminal for intimate contact with a power supply terminal for supplying power to electrodes provided on both sides of a plurality of channels formed in parallel with the planar fluorescent lamp. It relates to a flat fluorescent lamp that can be supplied by.

In general, LCD (LCD) devices, which are in the spotlight in flat panel display devices, are non-luminescent devices that do not emit their own light, and thus require a backlight device having a separate light source. Such backlight devices are classified into direct type and edge type.

The above methods are classified according to the position of the light source (lamp), and the edge type is a surface light source obtained by placing the light source on the side surface of the transparent light guide plate and reflecting and diffusing one side of the light guide plate to multi-reflect light. The direct type is a method of reflecting and diffusing light emitted from the light source by placing the light source directly under the LCD cell, and placing a diffuser plate on the front of the light source and a reflector plate on the back of the light source.

The direct type is suitable for a backlight requiring high luminance because high luminance can be obtained, but has a disadvantage of low luminance uniformity. On the other hand, the edge type has the advantage of low luminance but high luminance uniformity.

Meanwhile, flat fluorescent lamps have been developed that can maintain the advantages of the direct type and the edge type and compensate for the disadvantages. These flat type fluorescent lamps are shown in FIGS. 1 and 2.

1 is a perspective view showing a conventional flat fluorescent lamp, Figure 2 is a cross-sectional view showing a conventional flat fluorescent lamp.

As referred to herein, the flat fluorescent lamp 100 includes a first substrate 110 having a plurality of channels 111 formed at equal intervals, and the first substrate 110 to seal the inside of the channel 111. It consists of a plate-shaped second substrate 120 is installed on the bottom.

The first substrate 110 and the second substrate 120 are closely bonded by the adhesive 130.

In addition, discharge gas is injected into the channel 111.

Surface electrodes 141 for supplying power to the inside of the channel 111 are respectively provided on one end surface of the channel 111 and the bottom surface of one side of the second substrate 120.

On the other end surface of the channel 111 and the bottom of the other end of the second substrate 120, back electrodes 142 for supplying power to the inside of the channel 111 are provided.

The flat fluorescent lamp 100 is embedded in the backlight device, which will be described in detail with reference to FIG. 3.

As referred to herein, a lower support 210 is provided on an inner circumferential surface of the lower cover 200 having a receiving groove 201, and a flat fluorescent lamp 100 is provided on an upper surface of the lower support 210. It is installed.

The surface electrode 141 and the back electrode 142 provided at one end of the flat fluorescent lamp 100 are connected through a connection line 501, and a power supply line for supplying external power to the back electrode 142. 500 is connected, and the connection line 501 and the power supply line 500 are fixed by a soldering method.

An upper support 310 is installed around the upper surface of the flat fluorescent lamp 100, an LCD module 400 is installed on an upper surface of the upper support 310, and an upper surface of the LCD module 400. The upper cover 300 is installed.

That is, the flat fluorescent lamp 100 and the LCD module 400 accommodated in the lower cover 200 and the upper cover 300 are firmly fixed by the lower support 210 and the upper support 310.

Accordingly, power of the same polarity is applied to the surface electrode 141 and the back electrode 142 provided at one end of the channel 111, and the surface electrode 141 and the back electrode 142 provided at the other end of the channel 111. When power of the same polarity is applied to the light, light is generated in the channel 111.

However, in the related art, since the connecting line 501 and the power supply line 500 for supplying power to the flat fluorescent lamp 100 are fixed to the surface electrode 141 and the back electrode 142 by the soldering method, the electrode is damaged during the soldering operation. If the first substrate 110 and the second substrate 120 made of glass material is damaged due to the temperature variation, there is a problem.

In addition, there is a problem that inhibits the appearance due to the welding portion fixing the connection line 501 and the power supply line 500.

The present invention has been made to solve the above problems, the object of which is to fix the power supply terminal to the end of the power supply line for supplying power to the electrode and the power supply terminal in close contact with the electrode without damaging the power source It is to provide a flat fluorescent lamp that can supply a stable.

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

The backlight device using the flat fluorescent lamp of the present invention includes a flat fluorescent lamp formed by the bonding of the first substrate and the second substrate; A surface electrode formed at an edge of the first substrate; A back electrode formed at an edge of the second substrate; An upper cover surrounding an upper portion of the flat fluorescent lamp; A lower cover surrounding a lower portion of the flat fluorescent lamp; An upper support disposed between the upper cover and the flat fluorescent lamp to support the flat fluorescent lamp; A lower support disposed between the lower cover and the flat fluorescent lamp to support the flat fluorescent lamp; A first power supply terminal inserted between the upper support and the surface electrode and having a first contact protrusion formed at one end thereof and a first connector formed at the other end thereof; And a second power supply terminal inserted between the lower supporter and the back electrode and having a second contact protrusion formed at one end thereof and a second connector formed at the other end thereof.

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

Example 1

4 is a cross-sectional view showing a backlight device according to the present invention, Figure 5 is an exploded perspective view showing a power supply terminal of the backlight device according to the present invention.

The backlight device of the present invention is composed of a flat fluorescent lamp 100 and a structure surrounding the same.

Referring to FIG. 4, the flat fluorescent lamp 100 is formed by bonding the first substrate 110, which is an upper substrate, and the second substrate 120, which is a lower substrate. The surface electrode 141 serving as the first electrode is formed at the edge of the first substrate 110, and the back electrode 142 serving as the second electrode is formed at the edge of the second substrate 120.

The flat fluorescent lamp 100 is protected by a lower cover 200 having an upper cover 300 and a receiving groove 201. In addition, the LCD module 400 is disposed between the flat fluorescent lamp 100 and the upper cover 300, and the display hole 301 is exposed on the upper cover 300 to expose the LCD module 400. Formed.

In addition, the first substrate 110 is supported by the upper support 310, the second substrate 120 is supported by the lower support 210. The upper support 310 and the lower support 210 are formed of a molding material such as a silicon material to support the flat fluorescent lamp 100.

A second power supply terminal 700 is provided between the lower support 210 and the back electrode 142 to supply power to the back electrode 142.

The second power supply terminal 700 is formed of a conductive flat plate, and a second contact protrusion 711 is formed at one end thereof, and a second connector 710 is formed at the other end thereof. ) Is connected to the power supply line 500.

The second contact protrusion 711 is elongated in a horizontal direction of the channel 111, and a cross section thereof is formed in a semicircular shape.

In addition, although one second contact protrusion 711 may be formed, it is preferable to form at least two or more pieces at equal intervals.

A first power supply terminal 600 for supplying power to the surface electrode 141 is provided between the upper support 310 and the surface electrode 141.

The first power supply terminal 600 is made of a conductive flat plate, one end has a first contact protrusion 611, the other end is formed with a first connector 610, the first connector 610 ) Is connected to the power supply line 500.

The first contact first contact protrusion 611 is elongated in the horizontal direction of the channel 111, and a cross section thereof is formed in a semicircular shape.

In addition, although one first contact protrusion 611 may be formed, it is preferable to form at least two or more of the plurality of first contact protrusions 611 at equal intervals.

In order to increase the contact force between the first contact protrusion 611 and the surface electrode 141, an upper pressing protrusion 302 is formed on an inner circumferential surface of the upper cover 300, and the second contact protrusion 711 is provided. In order to increase the contact force between the back electrode 142 and the lower cover 200, the lower pressing protrusion 202 may be formed on the inner circumferential surface of the lower cover 200.

Meanwhile, a protrusion 311 is formed on the upper support 310 so that the first power supply terminal 600 is easily coupled and the combined first power supply terminal 600 does not flow. The protrusion 211 is formed on the lower support 210 so that the terminal 700 is easily coupled and the coupled second power supply terminal 700 does not flow.

The backlight device according to the present invention configured as described above has a first power supply terminal 600 and a second power supply terminal 700 for supplying power to the channel 111 provided in the flat fluorescent lamp 100. The upper support 310 and the lower support 210 are in contact with the surface electrode 141 and the back electrode 142.

In particular, the pressing force generated in the upper pressing protrusion 302 formed on the upper cover 300 is transmitted to the first contact protrusion 611 formed on the first power supply terminal 600 through the upper support 310, and the lower cover. The pressing force generated in the lower pressing protrusion 202 formed in the 200 is transferred to the second contact protrusion 711 formed in the second power supply terminal 700 through the lower support 210.

Therefore, the first contact protrusion 611 and the second contact protrusion 711 are in close contact with the surface electrode 141 and the back electrode 142 by the pressing force to stabilize the power supplied through the power supply line 500. Will be able to supply.

In addition, since the protrusions 311 and 211 formed on the upper support 310 and the lower support 210 maintain the state of being fitted to the first contact protrusion 611 and the second contact protrusion 711, the first power supply terminal 600 and the first The flow of the two power supply terminal 700 is to be prevented.

In addition, since the first power supply terminal 600 and the second power supply terminal 700 for supplying power to the flat fluorescent lamp 100 are contacted by pressing force, the surface electrode 141 and the back electrode are damaged due to soldering. At the same time to improve the appearance of the flat fluorescent lamp 100.

Example 2

6 is a perspective view showing a second embodiment of a power supply terminal for a backlight device according to the present invention.

As described herein, a first power supply terminal 600a for supplying power to the surface electrode 141 installed in the flat fluorescent lamp 100 and a second power supply terminal for supplying power to the back electrode 142. (700a).

A first contact protrusion 611a is formed at one end of the first power supply terminal 600a.

The first contact protrusion 611a is elongated in the vertical direction of the channel 111, and a cross section thereof is formed in a semicircular shape.

In addition, although one first contact protrusion 611a may be formed, it is preferable to form at least two or more of the plurality of first contact protrusions 611a at equal intervals.

The other end of the first power supply terminal 600a has a first connector 610a connected to the power supply line 500.

A second contact protrusion 711a is formed at one end of the second power supply terminal 700a.

The second contact protrusion 711a is elongated in the vertical direction of the channel 111, and a cross section thereof is formed in a semicircular shape.

In addition, although one second contact protrusion 711a may be formed, it is preferable to form at least two or more pieces at equal intervals.

A second connector 710a connected to the power supply line 500 is formed at the other end of the second power supply terminal 700a.

Accordingly, the first contact protrusion 611a formed at one end of the first power supply terminal 600a and the second contact protrusion 711a formed at one end of the second power supply terminal 700a may have a surface electrode 141 and a back electrode ( Since it is in close contact with the 142, the power supplied through the power supply line 500 connected by the soldering method to the first connector 610a and the second connector 710a is stably supplied to the surface electrode 141 and the back electrode 142. It is.

In addition, since the first power supply terminal 600a and the second power supply terminal 700a are in contact with the surface electrode 141 and the back electrode 142 by a pressing force, the surface electrode 141 and the back electrode of the surface electrode 141 due to soldering. At the same time to prevent damage and improve the appearance of the flat fluorescent lamp 100.

Example 3

7 is a perspective view showing a third embodiment of a power supply terminal for a backlight device according to the present invention.

As referred to herein, a first power supply terminal 600b for supplying power to the surface electrode 141 installed in the flat fluorescent lamp 100 and a second power supply terminal for supplying power to the back electrode 142. (700b).

A first contact protrusion 611b is formed at one end of the first power supply terminal 600b.

The first contact protrusion 611b is formed in a hemispherical shape.

One first contact protrusion 611b may be formed, but at least two or more first contact protrusions 611b may be formed at equal intervals.

The other end of the first power supply terminal 600b has a first connector 610b connected to the power supply line 500.

A second contact protrusion 711b is formed at one end of the second power supply terminal 700b.

The second contact protrusion 711b is formed in a hemispherical shape.

One second contact protrusion 711b may be formed, but at least two or more second contact protrusions 711b may be formed at equal intervals.

The other end of the second power supply terminal 700b has a second connector 710b connected to the power supply line 500.

Accordingly, the first contact protrusion 611b formed at one end of the first power supply terminal 600b and the second contact protrusion 711b formed at one end of the second power supply terminal 700b may have a surface electrode 141 and a back electrode ( Since it is in close contact with the 142, the power supplied through the power supply line 500 connected by the soldering method to the first connector 610b and the second connector 710b is stably supplied to the surface electrode 141 and the back electrode 142. It is.

In addition, since the first power supply terminal 600b and the second power supply terminal 700b are in contact with the surface electrode 141 and the back electrode 142 by the pressing force, the surface electrode 141 and the back electrode of the surface electrode 141 due to soldering. At the same time to prevent damage and improve the appearance of the flat fluorescent lamp 100.

 Example 4

8 is a perspective view showing a fourth embodiment of a power supply terminal for a backlight device according to the present invention.

As referred to herein, a first power supply terminal 600c for supplying power to the surface electrode 141 installed in the flat fluorescent lamp 100 and a second power supply terminal for supplying power to the back electrode 142. (700c).

A first contact protrusion 611c is formed at one end of the first power supply terminal 600c.

The first contact protrusion 611c is formed in a '+' shape intersecting in the vertical and horizontal directions of the channel 111, and a cross section thereof is formed in a semicircular shape.

The other end of the first power supply terminal 600c has a first connector 610c connected to the power supply line 500.

A second contact protrusion 711c is formed at one end of the second power supply terminal 700c.

The second contact protrusion 711c is formed in a '+' shape intersecting in the vertical and horizontal directions of the channel 111, and a cross section thereof is formed in a semicircular shape.

The other end of the second power supply terminal 700c has a second connector 710c connected to the power supply line 500.

Accordingly, the first contact protrusion 611c formed at one end of the first power supply terminal 600c and the second contact protrusion 711c formed at one end of the second power supply terminal 700c may have a surface electrode 141 and a back electrode ( Since it is in close contact with the 142, the power supplied through the power supply line 500 connected to the first connector 610c and the second connector 710c by the soldering method is stably supplied to the surface electrode 141 and the back electrode 142. It is.

In addition, since the first power supply terminal 600c and the second power supply terminal 700c are in contact with the surface electrode 141 and the back electrode 142 by a pressing force, the surface electrode 141 and the back electrode of the surface electrode 141 due to soldering. At the same time to prevent damage and improve the appearance of the flat fluorescent lamp 100.

Example 5

9 is a perspective view showing a fifth embodiment of a power supply terminal for a backlight device according to the present invention.

As referred to herein, a first power supply terminal 600d for supplying power to the surface electrode 141 installed in the flat fluorescent lamp 100 and a second power supply terminal for supplying power to the back electrode 142. (700d).

A first contact protrusion 611d is formed at one end of the first power supply terminal 600d.

The first contact protrusion 611d is formed in a '+' shape that crosses diagonally with respect to the vertical and horizontal directions of the channel 111, and a cross section thereof is formed in a semicircular shape.

The other end of the first power supply terminal 600d has a first connector 610d connected to the power supply line 500.

A second contact protrusion 711d is formed at one end of the second power supply terminal 700d.

The second contact protrusion 711d is formed in a '+' shape that crosses diagonally with respect to the vertical and horizontal directions of the channel 111, and a cross section thereof is formed in a semicircular shape.

At the other end of the second power supply terminal 700d, a second connector 710d connected to the power supply line 500 is formed.

Accordingly, the first contact protrusion 611d formed at one end of the first power supply terminal 600d and the second contact protrusion 711d formed at one end of the second power supply terminal 700d may have a surface electrode 141 and a back electrode ( Since it is in close contact with the 142, the power supplied through the power supply line 500 connected by the soldering method to the first connector 610d and the second connector 710d is stably supplied to the surface electrode 141 and the back electrode 142. It is.

In addition, since the first power supply terminal 600d and the second power supply terminal 700d are in contact with the surface electrode 141 and the back electrode 142 by the pressing force, the surface electrode 141 and the back electrode of the surface electrode 141 due to soldering are formed. At the same time to prevent damage and improve the appearance of the flat fluorescent lamp 100.

As such, the present invention prevents the surface electrode and the back electrode from being damaged since the power supply terminal for supplying power to the surface electrode and the back electrode of the channel formed in the flat fluorescent lamp is supplied in intimate contact with the pressing force. There is a unique effect that can be done.

In addition, since the soldering portion is not formed on the front electrode and the back electrode of the flat fluorescent lamp, there is a unique effect of improving the appearance of the flat fluorescent lamp and the backlight device provided with the flat fluorescent lamp.

Claims (15)

A flat fluorescent lamp formed by the bonding of the first substrate and the second substrate; A surface electrode formed at an edge of the first substrate; A back electrode formed at an edge of the second substrate; An upper cover surrounding an upper portion of the flat fluorescent lamp; A lower cover surrounding a lower portion of the flat fluorescent lamp; An upper support disposed between the upper cover and the flat fluorescent lamp to support the flat fluorescent lamp; A lower support disposed between the lower cover and the flat fluorescent lamp to support the flat fluorescent lamp; A first power supply terminal inserted between the upper support and the surface electrode and having a first contact protrusion formed at one end thereof and a first connector formed at the other end thereof; And And a second power supply terminal inserted between the lower support and the back electrode and having a second contact protrusion formed at one end thereof and a second connector formed at the other end thereof. The flat fluorescent lamp of claim 1, wherein the first contact protrusion and the second contact protrusion are formed by an embossment and an intaglio corresponding to the embossment on the first power supply terminal and the second power supply terminal which are conductive flat plates. Backlight device using a lamp. The backlight device of claim 1, wherein the first contact protrusion and the second contact protrusion are in contact with a surface of the flat fluorescent lamp. The backlight device of claim 1, wherein a lower pressing protrusion is formed on an inner circumferential surface of the lower cover, and an upper pressing protrusion is further formed on an inner circumferential surface of the upper cover. According to claim 1, The upper support and the lower support is provided with a projection is a backlight device using a flat fluorescent lamp, characterized in that coupled to the music of the first and second contact projections. The flat fluorescent lamp of any one of claims 1 to 5, wherein the first contact protrusion and the second contact protrusion are elongated in a horizontal direction of the channel, and a cross section thereof is formed in a semicircular shape. Backlight device using. The backlight device of claim 6, wherein at least two first contact protrusions and a plurality of second contact protrusions are respectively formed. The flat fluorescent lamp of any one of claims 1 to 5, wherein the first contact protrusion and the second contact protrusion are elongated in a vertical direction of the channel, and a cross section thereof is formed in a semicircular shape. Backlight device using. The backlight device of claim 8, wherein at least two first contact protrusions and a plurality of second contact protrusions are respectively formed. The backlight device according to any one of claims 1 to 5, wherein the first contact protrusion and the second contact protrusion are formed in a hemispherical shape. The backlight device of claim 10, wherein at least two first contact protrusions and a plurality of second contact protrusions are formed. The method according to any one of claims 1 to 5, wherein the first contact protrusion and the second contact protrusion are formed in a '+' shape intersecting in the vertical and horizontal directions of the channel, the cross section is a semicircle Backlight device using a flat fluorescent lamp, characterized in that formed. The backlight device of claim 12, wherein at least two first contact protrusions and a plurality of second contact protrusions are respectively formed. The method according to any one of claims 1 to 5, wherein the first and second contact projections are formed in a '+' shape intersecting in an oblique direction with respect to the vertical and horizontal direction of the channel, the cross section Backlight device using a flat fluorescent lamp, characterized in that formed in a semi-circular shape. The backlight device of claim 14, wherein at least two first contact protrusions and a plurality of second contact protrusions are formed.

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