KR101165846B1 - Backlight assembly - Google Patents

Abstract

A backlight assembly is disclosed that can reduce noise.

The backlight assembly of the present invention is characterized in that the electrode protrusion is formed on the support between the electrode fixing portions in the electrode plate comprising the plurality of electrode fixing portions having the plurality of lamps fixed and the supporting portion for supporting the electrode fixing portion, Since the electrode protruding portions are in close contact with each other, noise generated at the time of driving can be cut off.

Backlight assembly, liquid crystal display, protrusion, electrode plate, EEFL

Description

Backlight assembly

1 is an exploded perspective view schematically showing a direct-type backlight assembly having a conventional EEFL.

Fig. 2 is a detailed view of the electrode plate structure of Fig. 1; Fig.

3 is a cross-sectional view taken along the line A-A 'of the direct-type backlight assembly of FIG. 1;

4 is a view showing an electrode plate according to a first embodiment of the present invention.

FIG. 5 is a cross-sectional view illustrating a direct-type backlight assembly having the electrode plate of FIG. 4;

6 is a cross-sectional view illustrating a direct-type backlight assembly according to a second embodiment of the present invention;

Description of the Related Art

31, 41: electrode plate 31a, 41a:

31b, 41b: electrode fixing portion 31c: electrode protrusion

33, 49: lower structure 35, 43: upper structure

37, 45: rib

The present invention relates to a backlight assembly, and more particularly, to a backlight assembly capable of reducing noise.

The flat panel display includes a plasma display panel, a field emission display, a light emitting diode, and a liquid crystal display.

Since the liquid crystal display device is a light-receiving type device that can not emit light by itself and light is incident from the outside to form an image, there is a problem that an image can not be displayed in a dark place.

In order to solve such a problem, a liquid crystal display device is provided with a backlight assembly capable of irradiating light on its back surface.

Typical requirements for backlight assemblies include high brightness, high efficiency, uniformity of brightness, long life, thinness, light weight, and low cost. Typically, notebook monitors require a high-efficiency, long-life backlight assembly to reduce power consumption, and high-brightness backlight assemblies are required for general-purpose PC monitors and TVs.

As described above, the backlight assembly needs to have a high brightness. Currently, a cold cathode fluorescent lamp (CCFL) is a lamp that satisfies these conditions.

Such a cold-cathode fluorescent lamp obtains a high voltage required for holding the discharge start light of a cold-cathode fluorescent lamp by using a step-up transformer with a low alternating-current voltage of several tens kHz obtained from an LC resonance inverter. At this time, inverter output waveform is in the form of sine wave. Although the LC resonance inverter has a relatively simple device and high efficiency, it has a problem that a plurality of cold cathode fluorescent lamps can not be connected in parallel and driven by a single inverter. Therefore, inverters corresponding to the number of cold-cathode fluorescent lamps are required in an edge-type or direct-type backlight employing cold-cathode fluorescent lamps.

In order to overcome the disadvantages of such a cold cathode fluorescent lamp and to develop a backlight assembly capable of ensuring long life and light weight while ensuring high brightness and high efficiency of a liquid crystal display device of a trend toward a larger size, External Electrode Fluorescent Lamp (EEFL) has been developed.

Recently, a number of EEFLs are arranged directly under the backlight, and EEFL achieved high brightness of tens of thousands cd / m ² by high frequency driving of several MHz.

Such EEFLs can be driven by a single inverter by connecting a plurality of EEFLs in parallel.

The backlight assembly is divided into edge type and direct type according to the layout structure of the lamp. In the edge type backlight assembly, a lamp is disposed on a side surface, a light guide plate is disposed on the same plane as the lamp, a reflection plate is disposed on a bottom surface of the light guide plate, and a diffusion plate is disposed in front of the lamp. Accordingly, the light emitted from the lamp is partially incident on the diffusion plate directly forward by the light guide plate, another part is incident on the reflection plate, is reflected again, and then is incident on the diffusion plate.

On the other hand, the direct-type backlight assembly has a plurality of lamps arranged on the same plane, a reflection plate disposed on the bottom surface thereof, and a diffusion plate disposed on the front surface thereof. Thus, the light emitted from the plurality of lamps is incident on the diffusion plate in front of the rectangles. Therefore, the direct type rather than the edge type has been widely studied in recent years because it can irradiate light having a more uniform luminance forward.

1 is an exploded perspective view schematically illustrating a direct-type backlight assembly having a conventional EEFL. FIG. 2 is a view showing the electrode plate structure of FIG. 1 in detail.

1 and 2, a reflector 4 is formed on a lower cover 1 in a direct-type backlight assembly. The electrode plate 10 is fixedly fastened on the lower structure 7 separately from the lower cover 1 on which the reflector 4 is formed. A plurality of protrusions 13 are formed on the estuary structure 7 at predetermined intervals and a through hole 15 is formed at the position of the electrode plate 10 corresponding to the protrusions 13. The through holes 15 of the electrode plate 10 and the protrusions 13 of the lower mechanism 7 are aligned with each other so that the electrode plate 10 is closely contacted with the lower structure 7 . At this time, the protrusion 13 penetrating through the through hole 15 is not firmly fastened by another structure, but is simply inserted into the through hole 15 of the electrode plate 10 by the protrusion 13 of the lower structure 7, And is loosely fixed.

The electrode plate 10 includes a plurality of electrode fixing portions 10b for fixing the lamp 21 at predetermined intervals and a supporting portion 10a for supporting the electrode fixing portions 10b.

The lamp 21 is an EEFL. The extracellular electrode fluorescent lamp has a structure in which the extrinsic electrode 23 is formed on the outside of the non-electrode glass tube.

Therefore, the EEFL 21 is fixed to the electrode fixing portion 10b. The EEFL has an advantage that a plurality of EEFLs are electrically connected to a single electrode, so that a plurality of EEFLs can be emitted in parallel at one time.

The upper structure 17 is fastened and fixed to the lower structure 1 in a state where the EEFL 21 is fixed to the electrode fixing portion 10b of the electrode plate 10. [ The upper mechanism 17 is provided with a plurality of ribs 19 for fixing the support portion 10a between the electrode fixing portions 10b.

Therefore, when fastened between the upper structure 17 and the lower structure 1, the rib 19 of the upper structure 17 presses and fixes the support 10a of the electrode plate 10.

Thus, the conventional backlight assembly can simultaneously emit a plurality of EEFLs by connecting a plurality of EEFLs to the electrode plate.

However, as shown in Fig. 3, the EEFLs fixed in parallel are driven by an AC voltage having a predetermined driving frequency. Electrostatic force is generated as the (+) voltage and the (-) voltage are repeatedly applied to the EEFL by such a driving frequency, and the electrostatic force generates vibration in the EEFL and the electrode plate in which such EEFL is fixed. Therefore, noise is generated due to the friction between the electrode plate and the lower structure of the upper structure.

An object of the present invention is to provide a backlight assembly capable of reducing noise by changing the structure of a reflector.

According to a first aspect of the present invention, there is provided a backlight assembly comprising: a lower mechanism; An electrode plate fixed on the lower mechanism and having a plurality of electrode protrusions protruding forward; A plurality of lamps fixed on the electrode plate at predetermined intervals; And an upper mechanism having a rib closely attached to the electrode projection when fastened to the lower mechanism.

According to a second embodiment of the present invention, a backlight assembly comprises: a lower mechanism; An electrode plate fixed on the lower structure; A plurality of lamps fixed on the electrode plate at predetermined intervals; And an upper mechanism having an elastic member closely attached to the electrode plate when fastened to the lower mechanism.

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

FIG. 4 is a view illustrating an electrode plate according to a first embodiment of the present invention, and FIG. 5 is a cross-sectional view illustrating a direct-type backlight assembly having the electrode plate of FIG.

4, the electrode plate 31 of the present invention includes a plurality of electrode fixing portions 31b for fixing the EEFL at predetermined intervals, a supporting portion 31a for supporting the electrode fixing portions 31b, And an electrode protrusion 31c protruding at a predetermined height from the support 31a between the electrode fixing portions 31b. The electrode protrusion 31c protrudes from the support portion 31a between the electrode fixing portions 31b. Although the electrode projection 31c has a ladder shape in FIG. 4, it may have a round shape if necessary. The electrode protrusion 31c is preferably formed at a position corresponding to the rib of the upper mechanism described later.

The supporting portions 31a are arranged parallel to each other at a predetermined interval W and the electrode fixing portions 31b are formed at a predetermined interval L perpendicular to the supporting portions 31a arranged in this manner.

Therefore, the EEFL is fixed to the electrode fixing portion 31b. The EEFL has an advantage that a plurality of EEFLs are electrically connected to a single electrode, so that a plurality of EEFLs can be emitted in parallel at one time.

5, an electrode plate 31 having a plurality of EEFLs of FIG. 4 is fixed on the lower mechanism 33, and the lower mechanism 33 and the upper mechanism 35 are fixedly connected.

The rib 37 of the upper mechanism 35 is firmly brought into close contact with the electrode protrusion 31c of the electrode plate 31 when the lower mechanism 33 and the upper mechanism 35 are fastened together, There is no gap between the rib 37 of the upper mechanism 35 and the electrode protrusion 31c of the electrode plate 31. [

Therefore, even when the plurality of EEFLs are driven by the AC voltage having the driving frequency to generate the electrostatic force, the rib 37 of the upper mechanism 35 and the electrode protrusion 31c of the electrode plate 31 are tightly adhered to each other Friction is not generated and noise is originally blocked.

6 is a cross-sectional view illustrating a direct-type backlight assembly according to a second embodiment of the present invention.

In the first embodiment of the present invention, the electrode protrusion 31c is formed on the electrode plate 31 so as to tightly close the rib 37 of the upper mechanism 35 to block the noise.

In contrast, in the second embodiment of the present invention, an elastic member 47 capable of absorbing vibration is attached to the end of the rib 45 of the upper mechanism 43.

That is, the electrode plate 41 is composed of a plurality of electrode fixing portions 41b for fixing the EEFL at predetermined intervals and a supporting portion 41a for supporting the electrode fixing portions 41b.

The electrode plate 41 is fixed to a lower structure 49 on which a reflection plate (not shown) is formed. A plurality of ribs 45 positioned between the electrode fixing portions 41b are formed in the upper mechanism 43 fixed to the lower mechanism 49.

An elastic member 47 capable of absorbing vibration may be attached to the ends of the plurality of ribs 45. The elastic member 47 may be made of a rubber material or other soft elastic material.

The elastic member 47 is attached to the end of the rib 45 of the upper mechanism 43 so as to correspond to the support portion 41a between the electrode fixing portions 41b.

The elastic member 47 attached to the end of the rib 45 of the upper mechanism 43 is supported by the supporting portion of the electrode plate 41 The gap between the elastic member 47 and the support portion 41a of the electrode plate 41 can be prevented from being formed. Therefore, even if a plurality of EEFLs are driven with a predetermined driving frequency, there is no gap between the elastic member 47 and the support portion 41a of the electrode plate 41, friction is not generated between them, It will be blocked at its source.

As described above, according to the present invention, by forming the projecting portion on the support portion of the electrode plate, generation of noise during driving due to the driving frequency can be originally blocked.

According to the present invention, by attaching the elastic member to the rib end of the upper mechanism, it is possible to originally prevent generation of noise during driving due to the driving frequency.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

Claims (10)

Lower mechanism; An electrode plate fixed on the lower mechanism and having a plurality of electrode protrusions protruding forward; A plurality of lamps fixed on the electrode plate at predetermined intervals; And An upper structure having a plurality of ribs extending in the direction of the lower structure, / RTI > Wherein the rib and the electrode protrusion are in close contact with each other. The plasma display apparatus according to claim 1, A plurality of electrode fixing parts for fixing the lamp; And a supporting portion for supporting the electrode fixing portion, And the electrode protrusion is formed on the support portion. The backlight assembly of claim 2, wherein the electrode protrusion is formed on the support between the electrode fixing portions. The backlight assembly of claim 1, wherein the ribs are formed at positions corresponding to the electrode protrusions. The backlight assembly of claim 1, wherein the electrode protrusion has a shape of either a ladder shape or a round shape. The backlight assembly of claim 1, wherein the lamp is an extracellular electrode fluorescent lamp. Lower mechanism; An electrode plate fixed on the lower structure; A plurality of lamps fixed on the electrode plate at predetermined intervals; And An upper mechanism having a plurality of ribs extending in the lower mechanism direction; And an elastic member formed at an end of the rib, Wherein the elastic member is in close contact with the electrode plate. The plasma display device according to claim 7, A plurality of electrode fixing parts for fixing the lamp; A supporting portion for supporting the electrode fixing portion Lt; / RTI > And the ribs are formed to correspond to the support portions between the electrode fixing portions. delete The backlight assembly of claim 7, wherein the elastic member is made of one of a rubber material and an elastic material.

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