KR200393964Y1 - Back light unit equipped with prism means having pyramidal lenslet - Google Patents

Abstract

The present invention relates to a backlight unit for a light-receiving flat panel display device, and more particularly, the present invention relates to a shape of a lenslet that forms a prism means that serves to increase brightness on the surface of a flat panel display device by refracting and condensing light of a light source. In the form of a pyramid. The pyramid lenslet is formed on a light guide plate or formed on a separate sheet, so that the luminance is increased and uniformity even when two or more prism sheets are not used, as in the conventional backlight unit. will be.

A backlight unit having a prism means having a pyramid lenslet according to the present invention includes a light source; A light guide plate having a dot pattern formed on one surface thereof to guide light emitted from the imaginary light source; Reflecting means provided on a rear surface of the light guide plate; Diffusing means for scattering the light projected forward through the light guide plate to diffuse the light evenly over the entire surface of the light guide plate; And a prism means in which pyramid-shaped lenslets are continuously arranged in order to refract and condense the light irradiated from the light source to contribute to brightness enhancement.

Description

BACK LIGHT UNIT EQUIPPED WITH PRISM MEANS HAVING PYRAMIDAL LENSLET}

The present invention relates to a backlight unit for a light receiving flat panel display device,

In particular, the present invention has a pyramid shape of a lenslet that forms a prism means that serves to refract and condense the light of a light source to increase brightness on the surface of a flat panel display. The pyramid lenslet is formed on a light guide plate or formed on a separate sheet, so that the luminance is increased and uniformity even when two or more prism sheets are not used, as in the conventional backlight unit. will be.

In general, a light-receiving flat panel display such as an LCD or a light box, etc., injects a liquid crystal having an intermediate property between a solid and a liquid between two thin glass plates to change the arrangement of liquid crystal molecules upon power supply. This is a display that displays the image by generating contrast, and unlike PDP, FED, and organic ELD, it is a non-light-emitting type (light-receiving element), so it is impossible to use it without a separate light source. It requires a backlight unit in the form of a surface light source that can be maintained.

A key component of a conventional backlight unit (backlight unit) is a light source that determines luminance and chromaticity, such as a cold cathode fluorescent lamp (CCFL) or an LED, and the efficiency of light generated from the light source. Light guide plate (LGP) with a specially designed pattern pattern on the back surface of the transparent acrylic plate of PMMA resin to make the reflector to increase and the linear light received from the reflector to form a surface light source on the entire image display surface. )to be. In addition, the surface light source made by the three elements (light source, Reflector, LGP) is focused and diffused light efficiently by the diffusion sheet provided on the light guide plate. In addition, the upper surface of the diffusion sheet may be provided with a separate prism sheet to increase the light collecting efficiency.

Conventional prism sheet uses a large number of rectangular lenslets having a triangular cross section, and the desired quality cannot be obtained by using only one prism sheet, so that two or more prism sheets are used, and in particular, the prism is perpendicular to the rectangular lenslets. It was common to arrange sheets and use them.

However, there is a problem that the unit price increase caused by using more than one prism sheet and the implementation of a thinner display device is hampered.

The present invention has a pyramid shape of a lenslet constituting a prism means that serves to refract and condense the light of a light source to increase brightness on the surface of a flat panel display. The pyramid lenslet may be formed on the light guide plate or formed on a separate sheet to achieve desired luminance quality and moiré prevention with only one prism means, and the longitudinal and transverse boundary lines formed by the lenslet may be a virtual vertical line and It is an object of the present invention to provide a backlight unit capable of achieving a more perfect quality by deviating from an angle from a horizontal line.

In order to achieve the above object, a backlight unit having a prism means having a pyramid lenslet according to the present invention includes a light source; A light guide plate having a dot pattern formed on one surface thereof to guide light emitted from the imaginary light source; Reflecting means provided on a rear surface of the light guide plate; Diffusing means for scattering the light projected forward through the light guide plate to diffuse the light evenly over the entire surface of the light guide plate; And a prism means in which pyramid-shaped lenslets are continuously arranged in order to refract and condense the light irradiated from the light source to contribute to brightness enhancement.

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

As can be seen in Figure 1 showing an example applied to the display window of the mobile phone as a backlight unit according to the present invention, the backlight unit (U) is a light source, in particular the side view type (Side View Type) LED light source 10 The reflective sheet 30 and the bezel 20 are sequentially stacked on one side of the frame 40 on which the flexible printed circuit board (FPCB) 43 is mounted, and the other part of the frame 40 is stacked. On the side, a light guide plate 50, a diffusion sheet 60 having a light diffusion function, a prism means for ensuring luminance uniformity and preventing moiré phenomenon, and a range of light irradiated from the light source 10 is defined. It consists of a curtain tape (80).

The prism means may be formed on the back surface of the dot pattern forming surface of the light guide plate through injection (not shown), or may be formed by processing a pyramid-shaped lenslet through a roller process on a separate prism sheet 70.

As the light source 10, the LED can emit light of vivid color in a compact and efficient manner, and since it is a semiconductor device, there is no fear of loss, and excellent in initial driving characteristics and shock resistance, and strong in repetition of ON / OFF lighting. It is attracting attention by having.

The bezel 20 serves to protect the backlight unit, and the reflective sheet 30 serves to reflect back light exiting from the back of the light guide plate 50 and return it to the light guide plate 50.

The light guide plate 50 has a fine dot pattern formed on one surface by printing, etching, injection, or laser processing, and receives a light emitted from the LED using a transparent acrylic (or polycarbonate) panel, Through the formed dot pattern, the light is distributed evenly over the entire screen area.

The diffusion sheet 60 scatters the light of the light source and spreads the light evenly throughout the light guide plate 50. The diffusion sheet 60 is made of resin beads such as PET, and the binder is mixed. A light diffusing agent may be applied or one surface of the film may be embossed to form fine irregularities.

The stacking order of the reflective sheet 30, the light guide plate 50, the diffusion sheet 60, and the prism sheet 70 in the backlight unit U may be variously modified in addition to the illustrated general form.

In addition, the light guide plate 50, the reflective sheet 30, and the diffusion sheet 60 and the prism sheet 70 may be integrally formed, and for this reason, the concept of “sheet” is defined in the claims of the present specification. The terms "reflective means" and "spreading means" are used to cover.

The introduction of the diffusion function into the prism sheet is made of resin beads or the like, and a light diffusion agent mixed with a binder is applied to the prism sheet, or one surface of the prism sheet is embossed to form fine irregularities. Can be.

Although not shown, when the prism means according to the present invention is formed on the light guide plate 50, the pyramid redlets may be processed on the back surface of the dot pattern forming surface at once or through two or more injection processes.

1 and 2, when the prism means according to the present invention is implemented through a separate prism sheet 70, the pyramid lenslet 70A allows the sheet to pass between the pyramid-shaped rollers. (In Fig. 2, the lenslets are actually exaggerated, such as a magnified 300x magnification of a very fine lenslet).

The redslet processing of the prism means is more precise and controllable according to the member, material and purpose of the prism means is implemented, and it is preferable to select a processing method for securing cost competitiveness.

The prism sheet 70 is transparent in the visible region and should be flexible so that it can be adhered well when mounted on the backlight unit, and it is preferable to use polycarbonate, polyester, PMMA, PVC, Acryl-based polymer, and the like.

Hereinafter, the core of the backlight unit according to the present invention will be mainly described in the case that the prism means is implemented as a prism sheet. However, these features can be equally applied to the prism means implemented in other members.

The horizontal boundary line and the vertical boundary line formed by the lenslets of the prism sheet are preferably 0 to 20 degrees (differently expressed 90 to 110 degrees away from the virtual horizontal line and the vertical line). ), And more preferably 4 to 5 degrees (otherwise, 94 to 95 degrees deviate from the imaginary horizontal line and vertical line).

This is a problem that the maximum luminance increases when the lenslet cross-section of the conventional prism sheet has a triangular shape, but causes a very sharp luminance fluctuation depending on the vertical and horizontal viewing angles, that is, when the display device is viewed from a position where the viewing angle is 0 °. Although it is possible to see a clear image, the larger the viewing angle is to solve the problem that the brightness is significantly reduced and the moiré phenomenon occurs.

In particular, the flat panel display device employing only one prism having a vertical lenslet having a triangular cross section is not sufficient to offset the moiré phenomenon due to the ups and downs according to the vertical viewing angle with respect to the prism. Significant moiré phenomenon occurs due to the interference between the LCD panel and the prism due to the frequency difference between the LCD and prism mounted on U). To solve this problem, another prism is introduced and the lenslets of each prism are vertically crossed. In order to reduce moiré phenomena and obtain improved luminance quality (highness and uniformity), it was not possible to obtain the desired luminance quality.

Specifically, the moiré phenomenon occurs when two prisms conventionally used have the same frequency, and in order to remove the moiré phenomenon, it is preferable to change the spatial frequency of the two prisms. In order to have different spatial frequencies as described above, it is preferable to change the resolution of both prism surfaces, and as a method, it is preferable to change the number of lenslets per unit inch or the height of lenslets per unit inch.

Therefore, when the spatial frequencies of two prisms become integer multiples, the overlapping frequency (reinforcement phenomenon) occurs and the moiré phenomenon occurs due to this reinforcement phenomenon, so the spatial frequencies of the two prisms must be non-integer.

As a result of repeated experiments by the inventors of the present invention, this moiré phenomenon is characterized by the repetitive formation of the pyramid-shaped lenslets, in particular, the longitudinal and transverse boundary lines of the lenslets deviate by an angle from the imaginary vertical line and the horizontal line. The prism sheet 70 having such a pyramid lenslet increases the viewing angle of the backlight unit and increases the luminance according to the increased viewing angle, and the moiré phenomenon is the lenslet of the two prisms. It has been shown that moiré patterns can be reduced or eliminated by selecting the pitch of and the number of lenslets per unit inch.

When the LCD is mounted on a backlight unit having a pyramid-shaped lenslet according to the present invention, some visible band effect or moiré effect occurs in an off-axis state due to non-integer spatial frequency.

In particular, when the lenslet of the prism sheet in an asymmetrical form, better quality can be obtained.

In addition, the present invention is advantageous because it can contribute to manufacturing cost reduction and thinning of the display device, compared to the case of using two conventional prism.

In FIG. 2, a serration portion 70B formed of a protrusion (actually fine) having a semicircular cross section is formed at the edge of the prism sheet 70, so that the refractive and condensing efficiency may be further improved.

If necessary, in the backlight unit according to the present invention, a conventional prism sheet may be additionally introduced or two or more of the same or two types of prism sheets according to the present invention may be used.

In addition, a protrusion 71a is formed at an edge of the prism sheet 70, and a coupling groove 41 is formed in the frame 40 for accommodating the prism sheet 70 to accommodate the protrusion 71a. While the 70 is mounted on the frame 40 more easily in place, there is an effect that can prevent the prism sheet from shaking after being mounted.

Furthermore, the projections 51a and 61a are formed on the light guide plate 50 and the diffusion sheet 60 to provide convenience in arranging the frame 40 in a proper position when the frame 40 is mounted, and to prevent the shaking afterwards. Although not shown, protrusions may be formed in the reflective sheet 30, and coupling grooves for protrusions of the reflective sheet may be formed in the frame 40.

In FIG. 1, two protrusions 51a, 61a, and 71a are formed on three sides of each member, but the protrusions 51a, 61a, and 71a may be modified in various forming positions, protrusion shapes, and protrusion numbers.

As described above, the backlight unit having a prism means having a pyramid-shaped lenslet according to the present invention is a lenslet of a prism means that serves to increase luminance on the surface of a flat panel display device by refracting and condensing light of a light source. By having a pyramid shape, the desired brightness quality and moiré prevention can be achieved with only one prism means, and more perfect quality is realized by allowing the longitudinal and transverse boundary lines formed by the lenslets to deviate from the vertical and horizontal lines by an angle. This is possible.

In the above description of the present invention with reference to the accompanying drawings, but described mainly with a back light unit having a specific shape and structure, the present invention can be variously modified and changed by those skilled in the art, such variations and modifications are the scope of protection of the present invention Should be interpreted as belonging to.

1 is an exploded perspective view of a backlight unit according to the present invention,

2 is a view related to the prism sheet of the backlight unit according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: light source 20: bezel

30: reflective sheet 40: frame

41: engaging groove 43: FPCB

50: light guide plate 60: diffusion sheet

70: prism sheet 80: curtain tape

U: backlight unit

Claims (9)

Light source; A light guide plate having a dot pattern formed on one surface thereof to guide light emitted from the light source; Reflecting means provided on a rear surface of the light guide plate; Diffusing means for scattering the light projected forward through the light guide plate to diffuse the light evenly over the entire surface of the light guide plate; And And a prism means having a pyramid-shaped lenslet comprising a prism means in which pyramid-shaped lenslets are continuously arranged in order to refract and condense the light irradiated from the light source to improve brightness. The method of claim 1, And a prism means having a pyramid lenslet, wherein the prism means is formed on the back surface of the dot pattern forming surface of the light guide plate. The method of claim 1, The prism means is a backlight unit having a prism means having a lenslet of a pyramid shape, characterized in that consisting of a separate prism sheet. The method of claim 2 or 3, And a transverse boundary line and a longitudinal boundary line formed by the lenslets of the prism means are 0 to 20 degrees away from the virtual vertical line and the virtual horizontal line, respectively. The method of claim 4, wherein And a transverse boundary line and a longitudinal boundary line formed by the lenslets are respectively 4 to 5 degrees away from the virtual vertical line and the virtual horizontal line. The method of claim 2 or 3, The lens unit of the prism means is a backlight unit having a prism means having a pyramidal lenslet, characterized in that the asymmetrical form. The method of claim 2 or 3, Backlight unit having a prism means having a pyramid lenslet, characterized in that it further comprises a curtain tape for limiting the range of light irradiated from the light source. The method of claim 2 or 3, And a prism means having a pyramid lenslet, wherein the lenslet of the prism means is injection molded. The method of claim 2 or 3, Protrusions are formed on the edge of the member forming the prism means, The backlight unit having prismatic means characterized in that the coupling groove for the projection is formed in the frame for receiving the components of the backlight unit.