KR100634753B1 - Back-light unit of direct lighting type liquid crystal display - Google Patents

Abstract

The present invention relates to a backlight structure of a direct type liquid crystal display device, and more particularly, in the direct type backlight method, the shape of both electrodes of a fluorescent lamp providing a light source is formed in a detachable cap form that can be inserted into a socket. A backlight structure of a direct type liquid crystal display device for facilitating replacement of a fluorescent lamp.

In the fluorescent lamp according to the present invention, the shape of the end of the conductive metal rod drawn out from the electrode was changed into a disk shape, and a socket corresponding to this shape was formed to configure the socket to serve as a relay between the fluorescent lamp and the wire.

In addition, the distance between the mold frame to which the socket is fixed, the role of a holder for fixing the fluorescent lamp was added.

When the fluorescent lamp is replaced in the liquid crystal display device having such a direct backlight structure, only the fluorescent lamp to be replaced can be separated separately, so that the fluorescent lamp can be easily separated and the additional loss occurring during the replacement is prevented. In addition, there is an effect that the parts are simplified and simplified.

Socket, fluorescent lamp

Description

Back-light unit of direct lighting type liquid crystal display

1 is a plan view of a conventional backlight assembly.

Figure 2a is a preferred embodiment according to the present invention.

Figure 2b is a cross-sectional view of the socket according to the present invention.

The present invention relates to a backlight of a direct type liquid crystal display device, and more particularly, to a removable type in which a shape of an electrode at both ends of a fluorescent lamp providing a light source can be inserted into a socket in a direct type liquid crystal display device. The present invention relates to a backlight of a direct type liquid crystal display device in which only a fluorescent lamp can be replaced.

CRT (Cathode ray tube), one of the display devices that are generally used, is mainly used for monitors such as TVs, measuring devices, information terminal devices, etc., but the size and weight of electronic products are reduced due to the large weight and size of the CRT itself. Can't actively respond to the demands of

To replace these CRTs, liquid crystal displays (LCDs), which have the advantages of small size and light weight, have been actively developed, and the liquid crystal display device, which is a digital display device, is developing remarkably in the recent information society and its role is becoming important. have.

However, unlike the CRT, the liquid crystal display is not a light emitting device in which the liquid crystal directly generates light, but is a light receiving device that displays the screen by controlling the amount of light coming from the outside.

Therefore, in order to irradiate light on the liquid crystal panel, a separate light source, that is, a backlight device, must be used. Therefore, in order to improve the display quality of the liquid crystal display device, the performance of the backlight device as well as the liquid crystal display device should be recognized. have.

Such a backlight device is classified into a direct method and an edge method according to the position of the fluorescent lamp disposed.

Among these, large sized products use a direct backlight type in which a lamp is placed on the bottom of the liquid crystal panel to directly illuminate the front of the panel.

The direct backlight type has a fluorescent lamp as a light source at the bottom of the liquid crystal panel, and directly dims the front surface of the liquid crystal panel. Heat resistance and light uniformity problem remain to be improved.

Unlike the edge type by the light guide plate, the direct type backlight method uses a plurality of fluorescent lamps. When a lamp near the end of its life is generated among a plurality of fluorescent lamps, a portion of the liquid crystal panel is not provided with light, thereby causing a display defect. Therefore, the lamp at the end of its life is replaced.

However, the replacement of the backlight lamp leads to the replacement of the entire conventional lamp assembly shown in Fig. 1, because the structure of the conventional lamp assembly is provided with a power input rod 15 which provides an external power source to the electrode 10 for discharge. This is because the lamp wire 40 is integrally joined by soldering, and the lamp wire 40 is formed in one integrally connected with the lamp connector 50.

Therefore, among a plurality of lamp assemblies forming a direct backlight type, a lamp comprising a fluorescent lamp 20, a lamp wire 40, a lamp holder 30, and a lamp connector 50 for replacing a fluorescent lamp at the end of its life. This results in the replacement of the entire assembly, creating unnecessary waste.

An object of the present invention is to replace only the lamp unit when replacing the backlight lamp of the direct type liquid crystal display device.

Another object of the present invention will be described in detail in the configuration and operation of the present invention to be described later.

In the backlight of the direct type liquid crystal display according to the present invention, an inert gas is injected into a cylindrical glass tube, a fluorescent material is coated on an inner wall of the glass tube, and electrodes for discharging are formed at both ends of the cylindrical glass tube. A fluorescent lamp formed in the inner direction of the glass tube, and a conductive metal rod for supplying power to the electrode is drawn out of the electrode to the outside of the glass tube, and the end of the conductive metal rod is formed of a disc shaped metal cap; A receptacle for accommodating the metal cap of the shape is formed, the inner wall of the receptacle is connected to the socket and the conductive metal pad of the socket to form a conductive metal pad that can be in electrical contact with the disk-shaped metal cap and supplied from the inverter Consisting of a wire for transmitting the alternating current power supply to the metal cap of the disk of the fluorescent lamp.

With this structure, when the fluorescent lamp is replaced, the conductive metal rod and the disc cap are separated from the socket accommodating the conductive metal rod and the disc cap of the fluorescent lamp, so that the fluorescent lamp can be replaced.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2A shows a preferred embodiment of the present invention, which comprises a wire 40, a fluorescent lamp 20, a socket 100, and an inverter 60.

The wire 40 connects in parallel between the respective sockets 100 and an inverter (not shown) for providing AC power to the fluorescent lamp 20, and a conductive metal formed in each socket by the wires 40. Power is always supplied to the pad 103.

In the fluorescent lamp 110, an inert gas is injected into a cylindrical glass tube, a fluorescent material is coated on an inner wall of the glass tube, and electrodes for discharging are formed inwards at both ends of the cylindrical glass tube. A conductive metal rod for supplying power to the electrode is drawn outward from each electrode in the length direction of the glass tube, and the end of the conductive metal rod is formed by a disc shaped cap 115.

The socket 100 is provided with an accommodating part for accommodating the conductive metal rod of the fluorescent lamp 110 and the cap 115 in the form of a disc, and in the accommodating part, a conductive metal pad capable of being in electrical contact with the conductive metal rod 117 ( 103 is formed, and the conductive metal pad 103 and the wire 40 are connected through the inner body of the socket 100.

Two sockets 100 are formed in a pair to accommodate disc shaped caps 115 and conductive metal rods 117 formed at both ends of the fluorescent lamp 110, respectively, such as an inverter (not shown), a wire 40, An electrical circuit is formed that leads to the socket 100, the fluorescent lamp 110, the socket 100, the wire 40, and the inverter.

In addition, the bottom of the socket 100 is a mold frame (not shown), and a plurality of sockets 100 are arranged in the mold frame at predetermined intervals, and are fixed so as not to shake when accommodating each fluorescent lamp 20.

The inverter 60 is connected in series to a power supply unit (not shown) to receive DC power, and converts the DC power supplied from the power supply unit into AC power required by the fluorescent lamp 110, thereby providing a plurality of fluorescent lamps 110. As an electrical circuit to be supplied to the, a plurality of sockets 100 are connected in parallel between the output terminal of both sides of the inverter 60, the fluorescent lamp 110 accommodated in the plurality of sockets 100 is provided in the inverter 60 AC power is supplied.

FIG. 2B is a cross-sectional view of the socket 100 of FIG. 2A, in which a disk-shaped cap 115 of the fluorescent lamp 110 is accommodated in a storage space that appears in front, and a conductive metal pad 103 is disposed on a rear surface of the storage space. Is formed.

The conductive metal pad 103 and the wire 40 are connected through the body of the socket 100, and the AC power transmitted through the wire 40 is transferred to the conductive metal pad 103.

The depth of the storage portion formed in the socket 100 is a mold frame of the bottom surface of the glass tube of the fluorescent lamp 110 when the conductive metal rod 117 and the disc-shaped cap 115 drawn out from the fluorescent lamp 110 are accommodated. Formed at a height not in contact with

In addition, in order to prevent the end of the glass tube of the fluorescent lamp 110 from contacting the side of the socket 100, the length of the receiving portion formed in the socket 100 is shorter than the length of the combined metal rod and the disk-shaped cap. do.

By the above-described configuration, the socket 100 receives the power transmitted through the wire 40 from the conductive metal pad 103 and provides the cap 115 of the disc shape of the fluorescent lamp 110, The electrode 119 supplied with power through the conductive metal rod 117 connected to the cap 115 starts to discharge, and the movement of electrons generated by the discharge impinges with an inert gas inside the fluorescent lamp 110 to cause ultraviolet rays. The generated ultraviolet rays collide with the fluorescent material applied to the inner wall of the fluorescent lamp 110 to generate visible light to directly supply a light source to the liquid crystal panel (not shown).

To replace the fluorescent lamp 110 connected in this way, the conductive metal rod 117 connecting the fluorescent lamp 110 and the socket 100 and the disc-shaped cap 115 connected to the end of the conductive metal rod 117 When separated from the socket 100, the fluorescent lamp 110 is separated from the socket 100.

When the fluorescent lamp 110 is inserted into the socket 100, the conductive metal rod 117 of the fluorescent lamp 110 to be newly replaced and the disc-shaped cap 115 connected to the end of the conductive metal rod 117 are inserted into fluorescent light. Replacement of the lamp 110 is finished.

As described above, a plurality of sockets 100 designed to facilitate the separation of the fluorescent lamps 110 are spaced apart from each other by a predetermined distance on the bottom surface of the mold frame to which the sockets 100 are fixed. Not only serves to relay the power supplied to the 110, but also serves as a lamp holder for supporting both sides of the fluorescent lamp (110).

As described in detail above, the present invention has been described in detail with respect to preferred embodiments, but those skilled in the art to which the present invention pertains, various embodiments of the present invention without departing from the spirit and scope of the present invention It will be appreciated that the present invention may be modified or modified as described above.

In the liquid crystal display device having the direct backlight structure according to the present invention, when the fluorescent lamp in the backlight is replaced, only the fluorescent lamp to be replaced can be separated separately, so that the fluorescent lamp can be easily separated and replaced, and the fluorescent lamp can be replaced. This has the effect of preventing additional losses.

In addition, the socket replaces the functions of the lamp holder and the lamp connector of the related art, and there is an effect that the parts are simplified and simplified.

Claims (2)

An inert gas is injected into the glass tube, a fluorescent material is applied to the inner wall of the glass tube, discharge electrodes are formed inside both ends of the glass tube, and a disc shape is formed at the end of the metal rod extending outward from the discharge electrode. A fluorescent lamp in which a metal cap is formed; An accommodation part accommodating the metal cap is formed, a metal pad in electrical contact with the metal cap is formed on an inner wall of the accommodation part, and a socket to which a power supply wire is connected to the metal pad; And the metal cap is fitted to the housing so that the fluorescent lamp is detachably mounted to the socket. The direct type liquid crystal display of claim 1, wherein a plurality of fluorescent lamps are disposed, and the plurality of sockets corresponding to the plurality of fluorescent lamps are connected in parallel to an inverter for supplying AC power to the sockets. Backlight.

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