Source: https://patents.google.com/patent/JP3944170B2/en
Timestamp: 2019-12-05 23:51:07
Document Index: 102254885

Matched Legal Cases: ['art 40', 'art 50', 'art 60', 'art 40', 'art 50', 'art 60', 'art 40', 'art 50', 'art 60']

JP3944170B2 - Backlight unit - Google Patents
JP3944170B2
JP3944170B2 JP2004001815A JP2004001815A JP3944170B2 JP 3944170 B2 JP3944170 B2 JP 3944170B2 JP 2004001815 A JP2004001815 A JP 2004001815A JP 2004001815 A JP2004001815 A JP 2004001815A JP 3944170 B2 JP3944170 B2 JP 3944170B2
JP2004001815A
JP2004213025A (en
振 承 崔
桓 榮 崔
鎭 煥 金
2003-01-07 Priority to KR20030000780A priority Critical patent/KR100499140B1/en
2004-01-07 Application filed by 三星電子株式会社Ｓａｍｓｕｎｇ Ｅｌｅｃｔｒｏｎｉｃｓ Ｃｏ．，Ｌｔｄ． filed Critical 三星電子株式会社Ｓａｍｓｕｎｇ Ｅｌｅｃｔｒｏｎｉｃｓ Ｃｏ．，Ｌｔｄ．
2004-07-29 Publication of JP2004213025A publication Critical patent/JP2004213025A/en
2007-07-11 Publication of JP3944170B2 publication Critical patent/JP3944170B2/en
The present invention relates to a backlight unit, and more particularly, to an edge-emitting backlight unit using a light guide plate (LGP) and a point light source.
In general, flat panel displays are roughly classified into a light emitting type and a light receiving type. An example of the light receiving flat display is a liquid crystal display (LCD), but the LCD itself does not emit light to form an image, and light is incident from the outside to form an image. Cannot be observed. Therefore, a backlight unit is installed on the back of the LCD to emit light.
Depending on the arrangement of the light source, the backlight unit is a direct light emitting type in which a large number of lamps installed directly under the LCD directly irradiate light onto the liquid crystal panel, and a lamp installed at the edge of a light guide panel (LGP) Are radiated directly and transmitted to the liquid crystal panel.
The edge light emission type can use a line light source and a point light source as light sources. As a typical line light source, there is a cold cathode fluorescent lamp (CCFL) in which electrodes at both ends are installed in a tube, and as a point light source, there is a light emitting diode (LED: light emitting diode). CCFL has the advantage that it can emit strong white light and can obtain high brightness and high uniformity and can be designed to have a large area, but it has the disadvantage that the operating temperature range is narrow by operating with a high frequency AC signal. is there. The LED has lower performance than the CCFL in terms of brightness and uniformity, but operates with a DC signal, has a long life, and has a wide operating temperature range. In addition, it has the advantage that it can be made thinner.
LGP is used in an edge light emission type backlight unit, and converts light incident through an edge from a line light source or a point light source into surface light to emit light in a vertical direction. In LGP, a scattering pattern and a hologram pattern are formed by a printing method or a machining method in order to convert light incident from a light source into surface light.
FIG. 1 is a schematic perspective view of a conventional edge-emitting backlight unit using a point light source, and FIG. 2 is a cross-sectional view of the edge-emitting backlight unit shown in FIG. According to FIG. 1, three LEDs 20 are installed as point light sources at the edge 11 of the LGP 10. On the bottom surface of the LGP 10, a hologram pattern 30 for emitting light incident from the LED 20 to the light exit surface 12 is formed.
The LED 20 emits light toward the edge 11 of the LGP 10. Since the LED 20 is a point light source, it emits light in the range of azimuth angle ± 90 ° with the optical axis as the center as shown in FIG. At this time, an azimuth angle at which light having an intensity (Imax / 2) corresponding to half of the maximum value Imax of the light intensity is emitted is referred to as a full width half maximum (FWHM). In the case of an LED, the FWHM is usually about ± 45 °.
The light emitted from the LED 20 enters the LGP 10 through the edge 11 and enters the hologram pattern 30. The hologram pattern 30 has a diffraction grating structure, converts incident light into surface light, and emits it to the light exit surface 12 which is the upper surface of the LGP 10. Although the hologram pattern 30 is formed with a certain directionality, light can be emitted with the highest efficiency when light is incident on the hologram pattern 30 at an angle of about 90 °. In addition, as the incident azimuth distribution of the light incident on the hologram pattern is smaller, a uniform luminance on the light exit surface 12 can be obtained. If the brightness of the light exit surface 12 is not uniform, the screen appears to be stained. In a narrow area of about 1 cm, a luminance change of about 0.9 is detected as a stain, but if there is a slow luminance change from the center to the tip of the screen, the luminance stain is detected even if it is about 0.8. Not. Accordingly, a luminance uniformity of 0.8 or more is required, and a luminance uniformity of 0.9 or more is required to obtain a high quality image.
FIG. 4 is a diagram showing a light output distribution by the conventional backlight unit shown in FIG. 1, and the LGP 10 is arranged in order from the edge 11 where the LED 20 is installed to the light incident part 40, the central part 50, The light output distribution of the light emitted to the light output surface 12 is divided into three regions of the part 60. According to FIG. 4, compared with the light incident part 40, the central part 50 and the light receiving part 60 have a wider light emission distribution.
FIG. 5 is a graph showing the luminance at the light exit surface 12 by the edge light emission type backlight unit shown in FIG. The vertical axis represents luminance, and the horizontal axis represents the light exit angle on the light exit surface 12 as FWHM. Three curves C1, C2, and C3 represent the luminance of the light incident portion 40, the central portion 50, and the light facing portion 60, respectively. According to FIG. 5, it can be seen that the luminance of the light incident part 40 is higher than the luminance of the central part 50 and the light-receiving part 60. The FWHM is 20 ° / 20 ° at the light incident portion 40, but is more widely shown at 20 ° / 35 ° at the central portion 50 and the light-receiving portion 60. The front 20 ° and the rear 35 ° at 20 ° / 35 ° are the FWHMs in the X and Y directions shown in FIG.
The reason why the luminance is non-uniform is that the distribution of the incident azimuth angles of the light incident on the hologram pattern 30 at the central portion 50 and the counter light portion 60 is larger than that at the light incident portion 40. That is, at the central portion 50 and the light-receiving portion 60 far from the LED 20, light having various incident azimuth angles is incident on the hologram pattern 30 through several reflection processes as shown in FIG. Because. Such brightness non-uniformity becomes more severe as the incident azimuth distribution of light emitted from the LED 20 and incident on the LGP increases.
The present invention was created to solve the above-mentioned problems, and an edge improved to improve the luminance uniformity of the light exit surface by narrowing the azimuth angle of the light incident on the LGP from the point light source. The purpose is to provide a light-emitting backlight unit.
1st invention of this application is interposed between the light source plate in which the hologram pattern was formed, at least one point light source which projects light on the edge of the light guide plate, the point light source, and the light guide plate, A refractive member that has an incident surface on which light from a point light source is incident and an exit surface that emits the light incident on the incident surface to the light guide plate, and narrows the azimuth angle of the light incident on the light guide plate The refractive member is formed flat on the exit surface at a position facing the point light source, and transmits light substantially parallel to the optical axis of the light from the point light source as it is, It is formed on the exit surface subsequent to the light transmitting region, such a first surface parallel to the optical axis, and a second surface forming a predetermined angle with respect to the first surface, a toothed saw Suyo The first surface and the second surface are arranged to face each other in this order from the point light source side. A blazed area formed with a blazed pattern into which light from the point light source is incident, and a first inclined surface formed on the exit surface following the blazed area and having a predetermined angle with respect to the optical axis; The second inclined surface is opposed so as to be centered on an apex of a triangle whose bottom surface is a surface orthogonal to the optical axis, and light from the point light source and light from the point light source adjacent to the point light source And an angle formed by the second surface of the blaze pattern with a line perpendicular to the optical axis is greater than the maximum azimuth angle of light passing through the blaze region. large and the triangular angle which the first and second inclined surfaces makes with a line perpendicular to the optical axis of the prism pattern backlight unit you being greater than the maximum azimuth angle of light passing through the prism area To provide.
According to a second invention of the present application, in the first invention, the light transmission region is formed so as to pass light having an azimuth angle in a range of about 0 to ± 9 ° to 0 to ± 16 ° in the refractive member. A backlight unit is provided.
A third invention of the present application provides the backlight unit according to the first invention, wherein the triangular prism pattern has an apex angle of about 28 to 45 °.
A fourth invention of the present application provides the backlight unit according to the first invention, wherein the pitch of the triangular prism pattern in the prism region is about 50 μm.
A fifth invention of the present application provides the backlight unit according to the first invention, wherein the pitch of the blaze pattern is about 50 μm.
A sixth invention of the present application provides the backlight unit according to the first invention, wherein the refractive member is formed integrally with the light guide plate.
A seventh invention of the present application provides the backlight unit according to the first invention, further comprising a diffusing member that diffuses light emitted from the point light source and incident on the refractive member.
An eighth invention of the present application provides the backlight unit according to the seventh invention, wherein the diffusing member is formed integrally with the refractive member by forming a concave curved surface on the incident surface of the refractive member. To do.
A ninth invention of the present application provides the backlight unit according to the first invention, wherein a length of the first side is longer than a pitch length of the blaze pattern.
The tenth invention of the present application includes a light guide plate on which a hologram pattern is formed, at least one point light source that projects light onto an edge of the light guide plate, a diffusion member that diffuses light emitted from the point light source, 1. A backlight unit comprising the refractive member according to the invention.
According to an eleventh aspect of the present invention, in the tenth aspect , the light transmission region is formed so that light having an azimuth angle in the refractive member of about 0 to ± 9 ° to 0 to ± 16 ° is allowed to pass through. A backlight unit is provided.
The twelfth invention of the present application is the backlight according to the tenth invention, wherein an angle formed between the inclined surface of the triangular prism pattern and a line perpendicular to the optical axis is larger than a maximum azimuth angle of light passing through the prism region. Provide units.
A thirteenth invention of the present application provides the backlight unit according to the tenth invention, wherein an apex angle of the triangular prism pattern is about 28 to 45 °.
A fourteenth invention of the present application provides the backlight unit according to the tenth invention, wherein the pitch of the triangular prism pattern in the prism region is about 50 μm.
A fifteenth invention of the present application is the backlight unit according to the tenth invention, wherein an angle formed by an inclined surface of the blaze pattern and a line perpendicular to the optical axis is larger than a maximum azimuth angle of light passing through the blaze region. I will provide a.
A sixteenth invention of the present application provides the backlight unit according to the tenth invention, wherein the pitch of the blaze pattern is about 50 μm.
A seventeenth invention of the present application provides the backlight unit according to the tenth invention, wherein the refractive member is formed integrally with the light guide plate.
An eighteenth invention of the present application provides the backlight unit according to the tenth invention, wherein the diffusing member is formed integrally with the refracting member by forming a concave curved surface on the incident surface of the refracting member. To do.
According to the backlight unit of the present invention, the following effects can be obtained.
First, the efficiency of the hologram pattern that emits light to the light exit surface can be improved by reducing the incident azimuth distribution of the light incident on the LGP.
Second, the intensity distribution of light emitted to the light exit surface becomes uniform, and the brightness uniformity on the light exit surface is improved.
Third, the use of a diffusing member can prevent or minimize dark areas between point light sources.
FIG. 6 is a perspective view showing an embodiment of a backlight unit according to the present invention.
According to FIG. 6, three LEDs 120 are installed as point light sources at an edge 111 of an LGP (Light Guide Panel) 110, and a refractive member 200 is installed between the LGP 110 and the LEDs 120. Between the LED 120 and the refractive member 200 and between the refractive member 200 and the LGP 110, for example, a medium having a refractive index smaller than that of the refractive member 200 or the LGP 110 is interposed, such as air.
LGP110 is made of a light-transmitting material that transmits light, but acrylic transparent resin (PMMA) with a refractive index of 1.49 and a specific gravity of about 1.19 is mainly used. An olefin-based transparent resin having a value of 1.0 may be used. The thickness of the LGP 110 is usually about 2 to 3 mm, and in order to reduce the weight, a wedge type in which the thickness becomes thinner as the distance from the edge on which light is incident may be used. The size of the LGP 110 depends on the size of an image display device (not shown) installed above the light exit surface 112, for example, an LCD. A hologram pattern 130 is formed on the LGP 110. A diffusion plate (not shown) for diffusing light is installed above the light exit surface 112.
The hologram pattern 130 diffracts the light incident through the edge 111 of the LGP 110 and emits it to the light exit surface 112, and is provided on the bottom surface of the LGP 110 in FIG. 6. The hologram pattern 130 is formed by repeatedly arranging diffraction gratings having a period of 2 μm or less. The hologram pattern 130 can be formed, for example, by repeatedly arranging diffraction gratings having a period of about 0.4 μm and a depth of about 0.2 μm. A reflection member (not shown) that reflects light transmitted through the hologram pattern 130 upward is installed below the hologram pattern 130. When the light is incident on the hologram pattern 130 at an angle of about 90 °, the light can be emitted with the highest efficiency. If the azimuth distribution of the light incident on the hologram pattern 130 is uniform, the luminance at the light exit surface 112 is uniform. Become.
The LED 120 is an example of a point light source, and emits light in an azimuth angle range of ± 90 ° around the optical axis as shown in FIG. At this time, an angle at which light having an intensity (Imax / 2) corresponding to half of the maximum value Imax of light intensity is emitted is referred to as FWHM. In the case of an LED, the FWHM is generally about ± 45 °. In this embodiment, three LEDs 120 are provided on the left edge 111 side of the LGP 110. However, since the number of LEDs 120 depends on the size of the LGP 110 and the required luminance, more LEDs 120 may be installed. Further, the LED 120 may be further installed not only at the edge 111 but also at another edge of the LGP 110.
The refracting member 200 is for refracting the light emitted from the LED 120 toward the optical axis 121 and narrowing the azimuth angle of the light incident on the LGP 110. The refracting member 200 is formed with a light transmission region 210 that transmits light near the optical axis 121 of each LED 120 as it is, a blaze region 220 in which a sawtooth blaze pattern is formed, and a triangular prism (prism) pattern. Prism region 230. The refraction member 200 can use the same material as the LGP 110, and in some cases, can use a material whose refractive index is larger or smaller than the LGP 110. The refractive member 200 can be manufactured by cutting or injection molding PMMA, olefin-based transparent resin, or the like.
FIG. 7 is a plan view showing in detail the refractive member shown in FIG. Referring to FIG. 7, the refractive member 200 according to the present embodiment uses PMMA having a refractive index of about 1.49, and the thickness, that is, the distance L1 between the incident surface 201 and the outgoing surface 202 is 5 mm. . The LED 120 is installed slightly away from the incident surface 201.
The light transmission region 210 from the optical axis 121 to the distance D1 is formed by not forming the prism pattern and the blaze pattern on the exit surface 202 as shown in FIG. 7, and is not shown in the drawing. It may be formed by cutting the member 200 from the optical axis 121 by a distance D1.
A region corresponding to D2-D1 is a blazed region 220 in which only light emitted from one LED is incident and light emitted from other adjacent LEDs is not incident. Accordingly, in the blaze region 220, the first surface 221 is parallel to the optical axis 121, and the second surface 222 is repeatedly arranged with a sawtooth blaze pattern having a predetermined angle with the optical axis 121. Further, the first surface 221 must be positioned on the optical axis 121 side. The pitch P2 of the blaze pattern is set to 50 μm in the present embodiment, but is not limited to this, and is appropriately selected in consideration of productivity and the light distribution from the light output surface 112.
In this example, D2 was set to about 3.6 mm. The LED 120 is placed away from the incident surface 202 of the refractive member 220, for example, about 0.05 mm. If the influence of this distance is ignored, since the refractive index of PMMA is about 1.49, the light incident on the refractive member 200 has an azimuth angle of about 42 ° at the maximum. If D2 is set to 36 mm because the distance L1 between the incident surface 201 and the exit surface 202 is 5 mm, light having a maximum azimuth angle of about 36 ° is incident on the blaze region 220.
In order for the light to be refracted toward the optical axis 121 while passing through the blazed region 220 and the azimuth angle be narrowed, the angle A at which the second surface 222 of the blazed pattern is orthogonal to the optical axis 121 is at least light passing through the blazed region 220. It is desirable to be larger than the maximum azimuth angle. In the case of this embodiment, it is desirable that the angle is larger than about 36 °. However, this does not limit the scope of the present invention, and it is desirable to determine the total light amount on the light exit surface 112, the light amount per unit solid angle, and the FWHM.
A prism region 230 is formed from D2 to the boundary with the blaze region of another adjacent LED. The prism region 230 is a region that is influenced by other adjacent LEDs, and is a region in which triangular prism patterns are repeatedly arranged so that the inclined surfaces 231 and 232 are refracting surfaces with the vertex at the center. Although the pitch of the triangular prism pattern is set to 50 μm in this embodiment, the scope of the present invention is not limited to this. The pitch of the triangular prism pattern is appropriately selected in consideration of productivity and the light distribution on the light output surface 112. In order for the light to be refracted toward the optical axis 121 side while passing through the prism region 230 and the azimuth angle be narrowed, the angle B formed by the inclined surfaces 231 and 232 of the triangular prism pattern and the line orthogonal to the optical axis 121 is the prism region. It is desirable that it be larger than the maximum azimuth angle of the light incident on 230. However, this does not limit the scope of the present invention, and it is desirable to determine the total light amount on the light exit surface 112, the light amount per unit solid angle, and the FWHM.
Further, since the blaze region 220 is a region that is not affected by other adjacent LEDs, D2 is the distance between the LEDs 120 and the refractive member 200 together with the total light amount on the light exit surface 112 of the LGP 110, the light amount per unit solid angle, and the FWHM. Is determined in consideration of the refractive index. It is desirable that the total light amount and the light amount per unit solid angle are large and the FWHM is small.
FIG. 8 is a graph showing the relationship between the apex angle of the triangular prism pattern and the light output distribution on the light output surface, where the pitch P1 of the triangular prism pattern is 50 μm and the light output is made while changing the distance d1 between the base and the apex. The total light quantity (flux) on the surface 112, the light quantity per unit solid angle, and the FWHM are measured. In order to improve luminance, it is desirable that the total light amount and the light amount value per unit solid angle are larger and the FWHM is smaller.
According to FIG. 8, the total light quantity hardly changes in the region where d1 is about 20 μm to 90 μm. It can be seen that the FWHM becomes smaller as d1 becomes larger and becomes the lowest from about 50 μm, and the light quantity per unit solid angle becomes the largest when it is about 60 μm or more. According to this experiment, when the distance d1 between the base and the apex is about 60 μm to 100 μm, an optimal light output distribution can be obtained on the light output surface 112. Therefore, when the pitch P1 is 50 μm, the apex angle is about 28 to 45 °, and the angle B formed by the inclined surfaces on both sides with the line orthogonal to the optical axis is about 67.5 to 76 °. The above-mentioned range of the apex angle has a meaning as an example of an optimum value selected by experiment, and does not limit the scope of the present invention.
FIG. 9 is a graph showing the relationship between the apex angle of the blaze pattern, the width of the light transmission region, and the light emission distribution on the light exit surface 112, where the pitch P2 of the blaze pattern is about 50 μm and the distance between the base and the apex. The amount of light per unit solid angle is measured while changing d2 and the width D1 of the light transmission region 210. P: P1 = 50 / d1 = 25 is a case where a triangular prism pattern having a pitch P1 of 50 μm and a distance d1 between the base and apex of 25 μm is formed instead of the blaze pattern, and B: P2 = 50 / d2 = 50 Indicates a case where a blaze pattern having a pitch P2 of 50 μm and a distance d2 between the base and apex of 50 μm is formed.
According to FIG. 9, when B: P2 = 50 / d2 = 50 and B: P2 = 50 / d2 = 60, P: P1 = 50 / d1 = 25 regardless of the width D1 of the light transmission region 210. The light quantity value per unit solid angle is even larger. When B: P2 = 50 / d2 = 25 and B: P2 = 50 / d2 = 12.5, the light quantity value per unit solid angle is smaller than P: P1 = 50 / d1 = 25. It is preferable that d2 is selected within a range in which the light quantity value per unit solid angle is larger than that in the case where the prism pattern is formed without forming the blaze pattern.
The width D1 of the light transmission region 220 is preferably determined so that the light quantity per unit solid angle is maximized. Therefore, referring to FIG. 9, about 0.8 to 1.4 mm from the optical axis 121. Can be selected. If this width D1 is converted into an angle from the optical axis 121, it becomes about 9 to 16 °.
FIG. 10 shows another embodiment of the backlight unit according to the present invention.
According to FIG. 10, the concave lens 240 is formed on the incident surface 201 of the refractive member 300. The concave lens 240 is an example of a diffusing member that diffuses light, and the light emitted from the LED 120 and incident on the concave lens 240 is Azimuth increases. Although the diffusing member of this embodiment is formed integrally with the refracting member 300, a separate concave lens can be installed between the LED 120 and the refracting member 200 in FIG. However, if the light passes through a large number of media, the light transmittance may be lowered. Therefore, it is more preferable that the light is formed integrally with the refractive member 300 as in this embodiment. The LED 120 is preferably located between the curved surface of the concave lens 240 and the center of a circle formed by the curved surface. The radius of curvature of the concave lens 240 can be appropriately selected in consideration of the total light amount on the light exit surface 112 of the LGP 110 and the light amount per unit solid angle.
When the concave lens 240 is not employed, the azimuth angle of the light inside the refractive member 200 is about 42 ° at the maximum when the refractive index of the refractive member 200 is 1.49. This angle is when light of 90 ° azimuth emitted from the LED 120 is incident on the refractive member. However, since the refractive member 200 and the LED 120 are slightly separated from each other, the maximum azimuth angle of light is actually smaller than 42 ° inside the refractive member 200. When the concave lens 240 is employed, light is diffused when entering the refractive member 300, so that the azimuth angle of the light within the refractive member 300 becomes larger than 42 ° depending on the curvature of the concave lens 240 and the installation position of the LED 120. This light passes through the light transmission region 210, the blaze region 220, and the prism region 230 formed on the exit surface 202 of the refractive member 300 and enters the LGP 110 with the azimuth angle narrowed.
In the above-described embodiment, the refractive members 200 and 300 are separately manufactured and installed between the LED and the LGP. The refractive members 200 and 300 may be manufactured integrally with the LGP 110. FIG. 11 shows still another embodiment of the backlight unit according to the present invention, in which an LGP 400 manufactured integrally with the refractive member 300 is illustrated.
Further, the operational effects of the above-described embodiment will be described.
Light emitted from the LED 120 is incident on the refractive members 200 and 300 through the incident surface 201. The azimuth angle of light inside the refractive member 200 is about ± 42 ° at the maximum when the refractive index of the refractive member 200 is 1.49. As shown in FIG. 10, when the concave lens 240 is employed, the light is diffused when entering the refractive member 300, so that the azimuth angle of the light inside the refractive member 300 becomes larger than 42 °.
Of these, light having an azimuth angle in the range of 0 ± 9 ° to 0 ± 16 ° is directly incident on the LGP 110 through the light transmission region 210. Of course, the azimuth angle is widened due to the difference in refractive index between the refractive members 200 and 300 and air when passing through the exit surface 202, but when incident on the LGP 110, the azimuth angle again becomes the same size. Therefore, the azimuth angle of the light passing through the light transmission region 210 in the LGP 110 is the same as the azimuth angle in the refractive members 200 and 300.
The blaze region 220 is a region where light emitted from other adjacent LEDs is not incident. As described above, the first surface 221 is formed in parallel with the optical axis 121, and the second surface 222 is formed with the optical axis 121. And make a certain angle. Therefore, only the second surface 222 acts as a refractive surface. The prism region 230 is a region where light emitted from other adjacent LEDs is also incident, and both the inclined surfaces 231 and 232 act as a refracting surface.
The light passing through the blaze region 220 and the prism region 230 has a narrow azimuth angle. When light travels from a medium with a high refractive index to a medium with a low refractive index, the outgoing angle is further expanded than the incident angle. Therefore, the light that has passed through the second surface 222 of the blaze pattern and the inclined surfaces 231 and 232 of the prism pattern is refracted toward the optical axis 121 and the azimuth angle is narrowed. This light is incident on the LGP 110 again. At this time, the light travels from a medium having a small refractive index to a medium having a large refractive index. Since the edge 111 of the LGP 110 is perpendicular to the optical axis 121, the azimuth angle is narrowed again.
Thus, if the azimuth angle of the light incident on the LGP 110 is narrowed, the light is incident on the hologram pattern 130 at an angle close to 90 °, so that the hologram pattern 130 can emit light with high efficiency. In addition, since the incident azimuth distribution of light incident on the hologram pattern 130 is uniform, the outgoing azimuth distribution of light emitted to the light exit surface 112 is also uniform. Therefore, the luminance uniformity on the light exit surface 112 is improved.
FIG. 12 and FIG. 13 are graphs showing luminance measurement results at the light incident part and the light-receiving part of the conventional backlight unit shown in FIG. 1, respectively, and FIGS. 14 and 15 are shown in FIG. 4 is a graph showing luminance measurement results at a light incident part and a light-receiving part according to an embodiment of the backlight unit according to the present invention. 12 to 15 show the measurement of the brightness of light passing through a diffusion plate (not shown) installed on the light exit surface of LGP.
According to FIGS. 12 and 13, the luminance distribution of the light-receiving portion appears wider than the luminance distribution of the light-receiving portion. However, according to FIGS. 14 and 15, it can be seen that the difference in luminance distribution between the light incident part and the light-receiving part is greatly reduced. This is because the azimuth angle of the light incident on the LGP 110 is narrowed by using the refractive members 200 and 300, so that the incident azimuth distribution of the light incident on the hologram pattern 130 is almost equal between the light incident portion and the opposite light portion. It means that it became the same.
There is a possibility that an intermediate area between the LEDs 120 is a dark area. FIG. 16 is a graph showing the amount of light in the LGP 110 when a diffusing member is employed as in the embodiment shown in FIG. According to FIG. 16, the light is diffused by the concave lens 240 and the azimuth angle of the light in the refractive member 300 is widened, so that a bright region appears as indicated by the reference symbol C between the LEDs 120. Therefore, if the light incident on the refractive member 300 is diffused by a diffusing member such as the concave lens 240, the generation of a dark region can be prevented or minimized.
The present invention is not limited to what has been described above and illustrated in the drawings, and many variations and modifications are possible within the scope of the claims.
The present invention can be applied to an edge light emitting type surface light source device that generates surface light for illuminating a flat type illuminated body, including an edge light emitting type backlight unit for illuminating a flat panel display.
It is a schematic perspective view of the conventional edge light emission type backlight unit which uses a point light source. FIG. 2 is a cross-sectional view of the edge light emission type backlight unit illustrated in FIG. 1. It is the graph which showed the radiation angle of LED. FIG. 2 is a diagram illustrating a light emission distribution by the conventional backlight unit illustrated in FIG. 1. 2 is a graph illustrating luminance on a light exit surface of the conventional backlight unit illustrated in FIG. 1. 1 is a schematic perspective view illustrating a first embodiment of a backlight unit according to the present invention. FIG. 7 is a plan view showing in detail the refractive member shown in FIG. 6. It is the graph which showed the relationship between the apex angle of a triangular prism pattern, and the light emission distribution in the light emission surface. It is the graph which showed the relationship between the apex angle of a blaze pattern, the width | variety of a light transmissive area | region, and the light emission distribution in the light emission surface. FIG. 6 is a perspective view showing another embodiment of a backlight unit according to the present invention. FIG. 6 is a perspective view showing still another embodiment of a backlight unit according to the present invention. FIG. 2 is a graph illustrating luminance measurement results at a light incident portion of the conventional backlight unit illustrated in FIG. 1. 2 is a graph illustrating luminance measurement results in a light-receiving portion of the conventional backlight unit illustrated in FIG. 1. FIG. 7 is a graph illustrating luminance measurement results at a light incident portion of the conventional backlight unit illustrated in FIG. 6. FIG. 7 is a graph illustrating luminance measurement results in a light-receiving portion of the conventional backlight unit illustrated in FIG. 6. FIG. 11 is a graph showing the amount of light in the LGP according to the embodiment shown in FIG. 10.
110 LGP
111 Edge 112 Light emitting surface 120 LED
121 Optical axis 130 Hologram pattern 200 Refraction member 210 Light transmission region 220 Blaze region 230 Prism region
A light guide plate on which a hologram pattern is formed;
At least one point light source that projects light onto an edge of the light guide plate;
The light source is interposed between the point light source and the light guide plate, and has an incident surface on which light from the point light source is incident, and an output surface that emits light incident on the incident surface to the light guide plate. And a refractive member that narrows the azimuth angle of the light incident on the light guide plate,
The refractive member is
A light transmission region that flatly forms the emission surface at a position facing the point light source and transmits light substantially parallel to the optical axis of the light from the point light source;
Is formed on the exit surface subsequent to the light transmitting region, and the optical axis parallel to the first surface, a second surface forming a predetermined angle with respect to the first surface, to name a toothed saw As described above, a blazed region in which a blazed pattern in which light from the point light source is incident is formed, facing each other in the order of the first surface and the second surface from the point light source side ,
A vertex of a triangle formed on the exit surface following the blaze region and having a first inclined surface and a second inclined surface that form a predetermined angle with respect to the optical axis, with the surface orthogonal to the optical axis as the bottom surface And a prism region in which a triangular prism pattern is formed on which light from the point light source and light from the point light source adjacent to the point light source are incident, and
The angle formed by the second surface of the blaze pattern and the line perpendicular to the optical axis is larger than the maximum azimuth angle of light passing through the blaze region, and the first and second inclined surfaces of the triangular prism pattern are the light beams. the backlight unit angle between the line perpendicular to the axis you being greater than the maximum azimuth angle of light passing through the prism area.
2. The light transmission region according to claim 1, wherein the light transmission region is formed to transmit light having an azimuth angle in the range of about 0 ± 9 ° to 0 ± 16 ° in the refractive member. Backlight unit.
The backlight unit according to claim 1, wherein the triangular prism pattern has an apex angle of about 28 to 45 degrees.
The backlight unit according to claim 1, wherein a pitch of the triangular prism pattern in the prism area is about 50 μm.
The backlight unit according to claim 1, wherein a pitch of the blaze pattern is about 50 μm.
The backlight unit according to claim 1, wherein the refractive member is formed integrally with the light guide plate.
The backlight unit according to claim 1, further comprising a diffusing member that diffuses light emitted from the point light source and incident on the refractive member.
The backlight unit according to claim 7 , wherein the diffusing member is formed integrally with the refracting member by forming a curved surface that is recessed in the incident surface of the refracting member.
The backlight unit according to claim 1, wherein a length of the first side is longer than a pitch length of the blaze pattern.
A diffusing member for diffusing the light emitted from the point light source;
A backlight unit comprising the refractive member according to claim 1.
The light transmission region, according to claim 10, characterized in that the azimuth angle in the refraction within member is formed to pass light of about 0 to ± 9 ° range to 0 to ± 16 ° range Backlight unit.
11. The backlight unit according to claim 10 , wherein an angle formed by the inclined surface of the triangular prism pattern and a line orthogonal to the optical axis is greater than a maximum azimuth angle of light passing through the prism region.
The backlight unit of claim 10 , wherein the triangular prism pattern has an apex angle of about 28 to 45 degrees.
The backlight unit according to claim 10 , wherein a pitch of the triangular prism pattern in the prism region is about 50 m.
11. The backlight unit according to claim 10 , wherein an angle formed by an inclined surface of the blaze pattern and a line perpendicular to the optical axis is larger than a maximum azimuth angle of light passing through the blaze region.
The backlight unit according to claim 10 , wherein the pitch of the blaze pattern is about 50 μm.
The backlight unit according to claim 10 , wherein the refractive member is formed integrally with the light guide plate.
The backlight unit according to claim 10 , wherein the diffusing member is formed integrally with the refracting member by forming a curved surface that is recessed in the incident surface of the refracting member.
JP2004001815A 2003-01-07 2004-01-07 Backlight unit Active JP3944170B2 (en)
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JP3944170B2 true JP3944170B2 (en) 2007-07-11
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