JP2008103200A - Backlight device and method for driving same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a backlight device capable of uniforming luminance of a light emitting surface and thinning. <P>SOLUTION: LEDs 1 are arranged on an entire surface of a substrate 2 of a back frame 6 so that each of three adjacent LEDs 1 constitutes each vertex of a regular triangle, and there are set a directional characteristics ψ of each of the LEDs 1, a distance h from each of the LEDs 1 to a diffusion plate, and an arrangement interval d of the LEDs 1, so as to satisfy a relationship formula d≤2htan(ψ/2). Therefore, a backlight device capable of uniforming luminance of a light emitting surface can be provided. In addition, by shortening the distance h between each of the LEDs 1 and the diffusion plate 3, thinning of the backlight device can be achieved while unevenness of a quantity of light incidenting on the diffusion plate 3 is reduced. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a backlight device using a light emitting diode.

  Since the liquid crystal used for the liquid crystal display does not emit light by itself, a light source such as a backlight is required. In the backlight method, a light source such as an LED (Light Emitting Diode) is arranged at the end of the liquid crystal panel, and a light guide plate method that diffuses light by providing a light guide plate, and a light source such as an LED is used for the liquid crystal panel. There is a direct system located on the back.

  The light guide plate type backlight device can reduce the thickness of the backlight. However, since the space for arranging the light source is limited, it is difficult to increase the size and increase the luminance.

On the other hand, a direct-type backlight device can be provided with a large number of light sources, and thus can be easily increased in size and brightness. Patent Documents 1 and 2 are known as direct-type backlights using LEDs.
JP 2006-120644 A JP 2006-133708 A

  However, in order to make the brightness of the light emitting surface uniform, the direct-type backlight device using LEDs needs to mix the light emission of each LED, and the distance between the light emitting surface and the LED must be separated, Thinning was difficult.

  The present invention has been made in view of the above, and an object of the present invention is to provide a backlight device that can make the luminance of the light emitting surface uniform and can be made thin.

  A backlight device according to a first aspect of the present invention is a backlight device including a plurality of LEDs and a diffusion plate that receives and diffuses light emitted from the LEDs, and the LEDs include three adjacent LEDs. Are arranged so as to form vertices of an equilateral triangle.

  In the present invention, by disposing the LEDs so that each of the three adjacent LEDs constitutes the apex of an equilateral triangle, the distance between the adjacent LEDs becomes equal, and the amount of light emitted to the diffusion plate varies. Therefore, the luminance of the light emitting surface of the backlight device can be made uniform.

  In the backlight device, assuming that the directivity characteristic of the LED is ψ, the distance from the LED to the diffusion plate is h, and the arrangement interval of the adjacent LEDs is d, the arrangement interval of the adjacent LEDs is d ≦ 2 h tan (ψ / 2). The above relational expression is satisfied.

  In the present invention, by setting the directivity characteristic ψ of the LED, the distance h from the LED to the diffusion plate, and the arrangement interval d of adjacent LEDs so that the relational expression d ≦ 2 h tan (ψ / 2) is satisfied. Since unevenness in the amount of light incident on the diffusion plate can be reduced, a backlight device in which the luminance of the light emitting surface is made uniform can be provided. In addition, by reducing the distance h from the LED to the diffusion plate so as to satisfy the relational expression of d ≦ 2h tan (ψ / 2), the unevenness of the amount of light incident on the diffusion plate is reduced and the backlight device Thinning is possible.

  In the backlight device described above, it is desirable that the directivity characteristic ψ of the LED is 30 ° ≦ ψ ≦ 90 ° because it is easy to distinguish the irradiation region for each LED.

  A driving method of a backlight device according to a second aspect of the present invention is the driving method of the backlight device, wherein a plurality of LEDs are divided into a plurality of LED groups each including a plurality of LEDs, and each of the LED groups is divided. The brightness is controlled.

  In the present invention, by dividing the arranged LEDs into a plurality of LED groups and controlling the luminance, the variation in the luminance of the LEDs can be corrected in units of LED groups, so the luminance of the light emitting surface is made uniform. A backlight device can be provided. In addition, luminance unevenness caused by a change in the temperature of the backlight device can be eliminated by controlling the luminance in units of LED groups.

  According to the present invention, it is possible to provide a backlight device in which the luminance of the light emitting surface is made uniform and the thickness can be reduced.

  Hereinafter, a backlight device according to an embodiment will be described with reference to the drawings. FIG. 1 is an exploded perspective view showing a configuration of a backlight device according to the present embodiment. The backlight device shown in FIG. 1 includes a back frame 6, a front frame 7, a diffusion plate 3 for reducing luminance unevenness between the back frame 6 and the front frame 7, a lens sheet 4, a diffusion sheet 5, and the like. The substrate 2 for arranging the LEDs 1 (not shown) is arranged on the inner surface of the back frame 6. Light emitted from the LED 1 passes through the diffusion plate 3, the lens sheet 4, and the diffusion sheet 5 and is emitted from the upper surface of the front frame 7.

  FIG. 2 is a plan view showing the arrangement of the LEDs 1 provided in the backlight device. The LEDs 1 are laid on the entire surface of the substrate 2 of the back frame 6 so that each of the three adjacent LEDs 1 forms an apex of an equilateral triangle. In this way, by arranging the adjacent LEDs 1 to have the same distance, the luminance of the light emitting surface of the backlight device can be made uniform.

  FIG. 3 is a cross-sectional view showing the arrangement of the LEDs 1 provided in the backlight device. In the figure, a substrate 2, an adjacent LED 1 disposed on the substrate 2, and a diffusion plate 3 are shown, and the luminous intensity in the normal direction 1a of the LED 1 and the normal direction 1a of the LED 1 is 100%. The luminous intensity half-value line 1b at which the luminous intensity of the LED 1 is 50% is shown. As shown in the figure, the LED 1 is arranged so that the adjacent LED 1 and the light intensity half-value line 1 b intersect on the diffusion plate 3. The amount of light incident on the point A where the normal direction 1a intersects the diffuser plate 3 is substantially equal to the amount of light incident on the point B where the luminous intensity half-value line 1b of the adjacent LED 1 intersects. Although the incident angle is different, the light emitted from the diffusion plate 3 is made uniform because the diffusion plate 3 sufficiently scatters the incident light.

Assuming that the directivity characteristic of the LED 1 is ψ, the distance from the radiation surface of the LED 1 to the diffusion plate 3 is h, and the arrangement interval of the adjacent LEDs 1 is d, the arrangement interval d of the LED 1 is d = 2h tan (ψ / 2). When satisfying, the luminous intensity half-value line 1b intersects on the diffusion plate 3 as shown in FIG. Note that the directivity of the LED 1 means that when the luminous intensity in the normal direction 1a of the LED 1 is 100%, the half-value angle θ _{1/2 at} which the luminous intensity is 50% when viewed from a direction inclined with respect to the light source is 2 It is a doubled value (2θ _1/2 ).

  As shown in the cross-sectional view of FIG. 4, when the arrangement interval of the LEDs 1 is narrow and the arrangement interval d ′ of the LEDs 1 is in a relationship of d ′ <2 h tan (ψ / 2), diffusion that is equidistant from the adjacent LEDs 1 The amount of light incident on the point C on the plate 3 is smaller than the amount of light incident on the point A on the normal direction 1a of the LED 1 because the point C exists inside the luminous intensity half-value line 1b. In addition, since the light 1c from the adjacent LED 1 is also incident at the point A, there is almost no difference in the amount of light incident on the point A and the point C, and the luminance of the light emitting surface can be made uniform.

  However, as shown in the cross-sectional view of FIG. 5, when the arrangement interval of the LEDs 1 is wide and the arrangement interval d ″ of the LEDs 1 is in a relationship of d ″> 2 h tan (ψ / 2), the adjacent LED 1 and the like Since the amount of light incident on the point D on the diffuser plate at a distance is smaller than the amount of light incident on the point A on the normal direction 1a of the LED 1, it will be visually recognized as luminance unevenness on the light emitting surface.

  Accordingly, by setting the directivity characteristic ψ of the LED 1, the distance h from the LED 1 to the diffusion plate, and the arrangement interval d of the adjacent LEDs 1 so that the relational expression d ≦ 2 h tan (ψ / 2) is satisfied, the luminance of the light emitting surface is set. Can be provided.

  Further, by reducing the distance h between the LED 1 and the diffusion plate 3 so as to satisfy the relational expression of d ≦ 2 h tan (ψ / 2), the backlight can be reduced while reducing the unevenness of the amount of light incident on the diffusion plate 3. The device can be made thin.

  FIG. 6 is a plan view showing an arrangement example of the LEDs 1 of the 32-inch backlight device in which each constant is set so as to satisfy the relational expression of d ≦ 2 h tan (ψ / 2). The LED 1 is arranged with the directivity characteristic of the LED 1 being ψ = 60 °, the distance from the LED 1 to the diffusion plate is h = 25 mm, and the arrangement interval of the LEDs 1 is d = 26 mm. In the example shown in the figure, LEDs 1 are arranged at equal intervals in parallel with the longitudinal direction of the backlight device, and adjacent columns are arranged in the other column so that each LED 1 constitutes a vertex of an equilateral triangle. It arrange | positions corresponding to the intermediate point of LED1 arrange | positioned. Further, the arrangement interval d of the LEDs 1 is set so that the locus 1e where the luminous intensity half-value line 1b intersects the diffusion plate 3 intersects at the approximate center of an equilateral triangle formed by three adjacent LEDs 1. In this way, the LED 1 constitutes the apex of an equilateral triangle, and the luminance half-value line 1b is arranged so that the locus 1e intersecting the diffuser plate 3 intersects, thereby eliminating the luminance unevenness of the light emitting surface 11 of the backlight device The luminance can be made uniform.

  FIG. 7 is a plan view showing another arrangement example of the LEDs 1 of the 32-inch backlight device in which each constant is set so as to satisfy the relational expression of d ≦ 2 htan (ψ / 2). Similar to the example shown in FIG. 6, the LED 1 is arranged with the directivity characteristic of the LED 1 being ψ = 60 °, the distance from the LED 1 to the diffusion plate is h = 25 mm, and the arrangement interval of the LEDs 1 is d = 26 mm. In the example shown in FIG. 7, an example is shown in which the LEDs 1 are arranged at equal intervals d perpendicular to the longitudinal direction of the backlight device. In the example shown in FIG. 6, 504 LEDs 1 are arranged, whereas in the example shown in FIG. 7, 512 LEDs 1 are arranged.

  The directivity characteristics of a general surface-mount type LED are about 120 °. However, if the directivity characteristics are narrowed, it becomes easy to distinguish the irradiation area for each LED. Therefore, the directivity characteristics ψ of the LED is 30 ° ≦ It is desirable that ψ ≦ 90 °. If the directivity characteristic ψ is too narrow, it may be necessary to reduce the arrangement interval d of the LEDs 1, or the light in the normal direction 1a of the LEDs 1 may be too strong, causing luminance unevenness on the light emitting surface.

  Next, an example in which the LEDs 1 arranged on the back frame 6 are divided and controlled for each group will be described. FIG. 8 is a plan view showing a state in which the LEDs 1 having the arrangement shown in FIG. 6 are divided into 12 groups of 3 vertical areas and 4 horizontal areas. By using an LED with a narrow directivity characteristic ψ and controlling each group divided into 12 by an independent circuit, it is possible to change the luminance in units of groups. Even when LEDs having different luminances are arranged separately for each group, the luminance of the light emitting surface of the backlight device can be made uniform by adjusting the current driven for each group.

  In addition, when using a backlight device, the temperature at the top and center of the backlight device increases and the brightness of the LED changes. Therefore, a temperature sensor is provided in the backlight device and feedback control is performed for each group. By doing so, the luminance of the light emitting surface of the backlight device can be made uniform.

  Further, by adjusting the brightness of the backlight device for each group in synchronization with the video signal, white spots of the liquid crystal can be prevented and a high-contrast liquid crystal display system can be provided. For example, when a white LED package in which a yellow LED is combined with a blue LED is used as the light source of the backlight device, the brightness can be controlled for each area, and red, green, and blue LEDs are combined. When the LED package is used, the luminance and chromaticity can be controlled. When red, green and blue LEDs are combined, it is necessary to mix each color sufficiently, so that each LED element is contained in one package or mixed sufficiently until light reaches the diffusion plate. However, it is necessary to reduce the distance between the LED elements so as to be white.

  In addition, the division | segmentation method which divides | segments LED for every group is not restricted to the example shown in FIG. 8, For example, you may divide | segment and control a group into a strip shape horizontally or vertically.

  As described above, according to the present embodiment, the adjacent three LEDs 1 are arranged on the substrate 2 of the back frame 6 so that each of the adjacent LEDs 1 constitutes the apex of an equilateral triangle. The luminance can be made uniform.

  According to the present embodiment, when the directivity characteristic of the LED 1 is ψ, the distance from the LED 1 to the diffusion plate 3 is h, and the arrangement interval of the adjacent LEDs 1 is d, the relational expression of d ≦ 2 h tan (ψ / 2). By setting each constant so as to satisfy the above, unevenness in the amount of light incident on the diffusion plate 3 is reduced, so that the luminance of the light emitting surface can be made uniform. Further, the backlight device can be thinned by shortening the distance h from the LED 1 to the diffusion plate 3 so as to satisfy the above relational expression.

  According to the present embodiment, the luminance can be adjusted for each group by controlling the plurality of LEDs 1 arranged on the substrate 2 of the back frame 6 separately for each group. And the luminance of the light emitting surface can be made uniform.

It is a disassembled perspective view which shows the structure of the backlight apparatus in one Embodiment. It is a top view which shows arrangement | positioning of LED of the said backlight apparatus. It is sectional drawing which shows arrangement | positioning of LED of the said backlight apparatus. It is sectional drawing which shows another arrangement | positioning of LED of the said backlight apparatus. It is sectional drawing which shows another arrangement | positioning of LED of the said backlight apparatus. It is a top view which shows arrangement | positioning of LED of the backlight apparatus in another embodiment. It is a top view which shows arrangement | positioning of LED of the backlight apparatus in another embodiment. It is a top view which shows the structure of the group which divided | segmented LED of the backlight apparatus of FIG. 6 for every group.

Explanation of symbols

1 ... LED
2 ... Substrate 3 ... Diffusion plate 4 ... Lens sheet 5 ... Diffusion sheet 6 ... Back frame 7 ... Front frame

Claims (4)

A backlight device comprising a plurality of LEDs and a diffuser plate for diffusing light emitted from the LEDs,
The LED is arranged so that each of the three adjacent LEDs constitutes the apex of an equilateral triangle.   When the directivity characteristic of the LED is ψ, the distance from the LED to the diffusion plate is h, and the arrangement interval of the adjacent LEDs is d, the arrangement interval of the adjacent LEDs is d ≦ 2 h tan (ψ / 2). The backlight device according to claim 1, wherein the relational expression is satisfied.   The backlight device according to claim 2, wherein the directivity characteristic ψ of the LED is 30 ° ≦ ψ ≦ 90 °. A driving method of the backlight device according to any one of claims 1 to 3,
A method for driving a backlight device, wherein the plurality of LEDs are divided into a plurality of LED groups each including a plurality of LEDs, and the luminance is controlled for each of the LED groups.

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