JP5867573B2 - Light emitting device - Google Patents

Description

The present invention relates to the technical field of light emitting devices . Specifically, an uneven pattern formed by a plurality of convex portions formed on the light exit surface of the light guide member is formed so as to satisfy a predetermined condition, thereby improving luminance uniformity and reducing leakage light by reducing luminance unevenness. It is related with the technical field which aims at reduction.

JP 2009-199926 A

  There is a light emitting device that performs illumination using a light source such as a light emitting diode (LED). The light emitting device is used, for example, as an illumination device using a light source as direct illumination, or used in an image display device such as a television receiver or a personal computer using a light source as backlight illumination.

  As such an image display device, for example, there is a liquid crystal display device used as a display panel on which a liquid crystal panel displays an image.

  In the liquid crystal display device, since the liquid crystal panel is not a self-luminous display, a light emitting device having a light source that emits light from the back side to the liquid crystal panel is disposed. Therefore, the light emitting device is used as a backlight device that irradiates light to the liquid crystal panel from the back side.

  A light-emitting device used as a backlight device has a light guide member, a light source is disposed on the side of the light guide member, and the light emitted from the light source is guided in a predetermined direction by the light guide member toward the display panel. There is a so-called side edge type for irradiation. In addition, a light-emitting device used as a backlight device includes a so-called direct type in which a light source is disposed on the back side of a display panel and light emitted from the light source is emitted toward the display panel.

  In the side-edge type light-emitting device, a plurality of light sources are arranged on the side of the light guide member, so that the image display device can be thinned.

  In such a side-edge type light-emitting device, when light is emitted from each of a plurality of light sources, each region predetermined for each light source of the light guide member, that is, each light source of the light guide member It is desirable that light is emitted from the region located on the side and that light does not leak into the adjacent region. In particular, in a light-emitting device referred to as a so-called scan backlight in which each band-like region is sequentially emitted to improve the definition of an image, there is a great need to reduce leakage light to adjacent regions.

  By reducing leakage light, it is possible to suppress a decrease in light utilization efficiency and a partial decrease in luminance.

  Some conventional light emitting devices have a plurality of grooves formed at predetermined intervals on the surface of a light guide member for the purpose of reducing such leakage light (see, for example, Patent Document 1).

  In the light emitting device described in Patent Document 1, the progress of light to the adjacent region is suppressed by the groove portion, and the leakage light to the adjacent region is reduced.

  However, in the image display device described in Patent Document 1, the light leakage in the adjacent region is reduced by the groove portion, but the light emission amount in the vicinity of the light emitting element is greatly different from the other portions. As a result, there is a problem that luminance unevenness deteriorates.

  On the contrary, if the number of grooves is reduced in order to suppress the deterioration of luminance unevenness, there arises a problem that light leakage to an adjacent region increases.

Therefore, the light-emitting device of the present invention has an object to solve the above-described problems and to improve the uniformity of luminance and reduce leakage light by reducing luminance unevenness.

In order to solve the above-described problems, in the light emitting device, one surface in the thickness direction is formed as a reflected light emitting surface on which light is internally reflected and emitted, and both side surfaces facing the direction orthogonal to the thickness direction are respectively light. A plate-shaped light guide member formed as a light incident surface on which light is incident, and a plurality of light guide members disposed opposite to the light incident surface of the light guide member and spaced apart in a first direction orthogonal to the thickness direction The light-emitting element is disposed opposite to the surface opposite to the reflected light emitting surface of the light guide member, and reflects the light reflected on the inner surface by the reflected light emitting surface and transmitted through the light guide member to reflect the light on the opposite side. A reflecting member that enters the light guide member from a surface, and is continuous with the reflected light exit surface of the light guide member in the first direction, and is perpendicular to both the thickness direction and the first direction. Light emitted from the light emitting element extending in the direction A concavo-convex pattern constituted by a plurality of convex portions to be surface-reflected is formed, an interval between the light emitting elements is L, a thickness of the light guide member is t, and an optical path from the light emitting element to the reflected light emitting surface is input. An angle formed by a line segment projected on a plane parallel to the light surface and a line segment extending from the center point of the light emitting element toward the reflected light emitting surface in the thickness direction is an incident angle φ of light with respect to the reflected light emitting surface, The maximum angle range that the reflected light can take when light incident at an incident angle φ is internally reflected by the reflected light exit surface is θ, and light is based on a line segment extending in the thickness direction of the angle range θ. When the range on the side approaching the light emitting element from which light is emitted is negative and the range on the side far from the light emitting element is positive, the incidence is in the range of 0 <φ <tan ⁻¹ (L / t). As the value of angle φ increases The value of the serial angle range θ is reduced, and, in the angular range θ is to span the range of both the negative range to the positive range, the protrusions parallel sectional shape the light incident surface The outer shape is formed in a shape in which two circular arcs are continuous, and is formed in a shape having a recess at the center in the first direction .

Therefore, in the light emitting device, 0 <φ <tan ^-1 In the range of (L / t), the angle range θ when it is incident on the reflected light exit surface at an incident angle φ and is internally reflected extends over both the positive range and the negative range.

In a third modified comparative example of the present invention, in a cross-sectional shape parallel to the light incident surface, a line segment connecting both ends of the convex portion in the first direction is defined as an X axis, and the middle of both ends of the convex portion. When the line segment passing through the point and extending in the thickness direction is the Y axis and the maximum height of the convex portion is a, the outer shape of the convex portion satisfies Y = −X ² / 4a + a .

The outer shape of the protrusion is Y = −X ² By satisfying / 4a + a, the light that is internally reflected through the focal point of the convex portion travels in the thickness direction of the light guide member.

In the first modified comparative example of the present invention, the convex portion is formed in a parabolic shape in cross section parallel to the light incident surface .

In the second modified comparative example of the present invention, the convex portion is formed such that the outer shape in the cross-sectional shape parallel to the light incident surface is a shape in which two arcs are continuous, and the center point in the first direction is the most. Located in front .

In the light emitting device of the present invention, one surface in the thickness direction is formed as a reflected light emitting surface on which light is internally reflected and emitted, and both side surfaces facing the direction orthogonal to the thickness direction are respectively incident light. A plate-shaped light guide member formed as a surface, a plurality of light-emitting elements arranged opposite to the light incident surface of the light guide member and spaced apart in a first direction perpendicular to the thickness direction, and the light guide The light that is disposed opposite to the surface opposite to the reflected light emitting surface of the member and reflected from the inner surface by the reflected light emitting surface and transmitted through the light guiding member is reflected from the surface on the opposite side to the light guiding member. A light-reflecting member that extends in a second direction that is continuous in the first direction and perpendicular to both the thickness direction and the first direction on a light-reflecting light-exiting surface of the light guide member. Multiple protrusions that reflect the emitted light internally Thus, a concavo-convex pattern is formed, the interval between the light emitting elements is L, the thickness of the light guide member is t, and the optical path from the light emitting element to the reflected light exit surface is parallel to the light incident surface. The angle formed by the projected line segment and the line segment extending from the center point of the light emitting element toward the reflected light emitting surface side in the thickness direction is defined as an incident angle φ of light with respect to the reflected light emitting surface, and is incident at the incident angle φ. The light emitting element in which light is emitted on the basis of a line segment extending in the thickness direction of the angle range θ, where θ is a maximum angle range that the reflected light can take when the light is internally reflected by the reflection light emitting surface. The value of the incident angle φ is large in the range of 0 <φ <tan ⁻¹ (L / t) when the range on the side approaching the light is negative and the range on the side far from the light emitting element is positive. The value of the angle range θ is small according to Becomes, and the angular range θ is to span the range of both the positive range to the negative range, the continuous outer shape are two arcs in parallel cross section to the light incident surface before the projecting portion It is formed in the shape which has a recessed part in the center part in the said 1st direction .

Therefore, unevenness in luminance in the light guide member can be reduced, and uniformity of luminance can be improved, and leakage light to other divided regions can be reduced.

It is a disassembled perspective view which shows an image display apparatus. It is a front view which shows a light guide member and a light source unit. It is a front view which shows the state from which the light guide member and the light source unit are light-emitted in one division area. It is an expansion perspective view which shows a part of light-emitting device. It is a conceptual diagram for demonstrating the shape of the uneven | corrugated pattern which concerns on a 1st modification comparative example with FIG. 6 thru | or FIG . It is a side view which shows a light emitting element, a light guide member, and a reflection member. 8 to 10 show the optical path when the light emitted from the light emitting element is internally reflected by the convex portion when the incident angle is different, and this figure shows the optical path when the incident angle is 0 °. FIG. It is a conceptual diagram which shows an optical path when an incident angle is larger than the incident angle of FIG. It is a conceptual diagram which shows an optical path in case an incident angle is larger than the incident angle of FIG. It is a conceptual diagram which shows an optical path when an incident angle is larger than the incident angle of FIG. It is a conceptual diagram which shows an optical path when the light which passes the focus of a convex part is reflected internally. In the uneven pattern according to the second modified comparative example together with FIG. 13, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for the case where the incident angle is different. It is a conceptual diagram which shows the optical path in case an angle is small. It is a conceptual diagram which shows an optical path when an incident angle is larger than the incident angle of FIG. In the concave-convex pattern according to the present invention together with FIG. 15, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for the case where the incident angle is different, and this figure shows the case where the incident angle is small It is a conceptual diagram which shows these optical paths. It is a conceptual diagram which shows an optical path in case an incident angle is larger than the incident angle of FIG. In the uneven pattern according to the first comparative example together with FIG. 17, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for different incident angles. It is a conceptual diagram which shows the optical path when is small. It is a conceptual diagram which shows an optical path when an incident angle is larger than the incident angle of FIG. In the uneven pattern according to the second comparative example together with FIG. 19, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for different incident angles. It is a conceptual diagram which shows the optical path when is small. It is a conceptual diagram which shows an optical path in case an incident angle is larger than the incident angle of FIG. In the uneven pattern according to the third comparative example together with FIG. 21, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for different incident angles. It is a conceptual diagram which shows the optical path when is small. It is a conceptual diagram which shows an optical path in case an incident angle is larger than the incident angle of FIG. In the uneven pattern according to the fourth comparative example together with FIG. 23, the optical path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for different incident angles. It is a conceptual diagram which shows the optical path when is small. It is a conceptual diagram which shows an optical path in case an incident angle is larger than the incident angle of FIG. In the uneven pattern according to the fifth comparative example together with FIG. 25, the light path when the light emitted from the light emitting element is internally reflected by the convex portion is shown for different incident angles. It is a conceptual diagram which shows the optical path when is small. It is a conceptual diagram which shows an optical path when an incident angle is larger than the incident angle of FIG. It is a conceptual diagram for demonstrating the uneven | corrugated pattern which concerns on a 3rd modification comparative example. It is a graph which shows the data which measured the illumination intensity in the light guide member in the position whose distance in the 2nd direction from the light-incidence surface is 10.5 mm. It is a graph which shows the data which measured the illumination intensity in the light guide member in the position whose distance in the 2nd direction from the light-incidence surface is 8.5 mm. It is a graph which shows the data which measured the illumination intensity in the light guide member in the position whose distance in the 2nd direction from the light-incidence surface is 12.5 mm. It is a graph which shows the data which measured the illumination intensity of all the division areas when light was radiate | emitted from the light emitting element located corresponding to one division area in the light guide member. It is a graph which expands and shows the part with the low illumination intensity ratio in the graph figure of FIG. It is a graph which shows the data which measured the illumination intensity of all the division areas when light was radiate | emitted from the light emitting element located corresponding to one division area in the light guide member. It is a graph which shows the data which measured illuminance in the light guide member in the position whose distance in the 2nd direction from the light-incidence surface is 5 mm. It is a graph which shows the data which measured the illumination intensity in the light guide member in the position whose distance in the 2nd direction from a light-incidence surface is 7 mm. It is a graph which shows the data which measured the illumination intensity in the light guide member in the position whose distance in the 2nd direction from a light-incidence surface is 9 mm.

EMBODIMENT OF THE INVENTION Below, the form for implementing this invention light-emitting device is demonstrated according to an accompanying drawing.

In the embodiment shown below, the light-emitting device of the present invention is applied to a light-emitting device provided in a television receiver that displays an image on a liquid crystal panel .

Note that the scope of application of the present invention is not limited to a television receiver having a liquid crystal panel and a light-emitting device provided in the television receiver, but to other various television receivers and various light-emitting devices used in personal computers. Can be widely applied.

[Configuration of image display device]
The image display device (television receiver) 1 is configured by arranging required parts inside an outer casing (not shown) (see FIG. 1).

  The outer casing is formed in a box shape that is opened forward and backward flat, and a display panel (liquid crystal panel) 2 that displays an image is disposed at a position that closes the opening from the inside. The display panel 2 is configured, for example, by sandwiching a transmissive color liquid crystal panel between two polarizing plates from the front and the rear, and displays a full color image by being driven by an active matrix system.

[Configuration of light emitting device]
A light emitting device 3 is arranged inside the outer casing (see FIGS. 1 to 4). The light emitting device 3 includes a reflection member 4, a light guide member 5, an optical sheet 6, and light source units 7, 7,. The reflection member 4, the light guide member 5, and the optical sheet 6 are sequentially disposed from the rear side, and the optical sheet 6 is disposed to face the display panel 2. The light source units 7, 7,... Are arranged on the side of the light guide member 5 in a state of facing the left and right side surfaces of the light guide member 5.

  The reflecting member 4 is formed in a plate shape by a resin or metal colored in white or silver, for example. The front surface of the reflecting member 4 is formed as a reflecting surface 4a.

  The light guide member 5 is formed in, for example, a rectangular thin plate shape, and is disposed between the reflection member 4 and the optical sheet 6. The light guide member 5 is made of a transparent material such as acrylic, polycarbonate, polystyrene, or glass.

  The light guide member 5 guides light emitted from the light source units 7, 7,... In a predetermined direction to enter the optical sheet 6, and the amount of light emitted from the optical sheet 6 toward the display panel 2. It has a function to make uniform.

  The light guide member 5 has a front surface, that is, one surface in the thickness direction is formed as a reflected light emitting surface 5a on which light is reflected and emitted, and both left and right side surfaces are emitted from the light source units 7, 7,. It is formed as light incident surfaces 5b and 5b on which the incident light is incident. The rear surface of the light guide member 5, that is, the other surface in the thickness direction is formed as a light control surface 5c through which light is transmitted or internally reflected. The light control surface 5c of the light guide member 5 is subjected to predetermined processing or processing for reflecting the light to the inner surface, and a part of the light reflected from the inner surface and not reflected from the inner surface is transmitted to the rear side. The The light transmitted rearward from the light control surface 5c is reflected by the reflection surface 4a of the reflection member 4, and is again incident on the light guide member 5 from the light control surface 5c.

  Of the two directions orthogonal to the thickness direction (front-rear direction) of the light guide member 5, the up-down direction is the first direction and the left-right direction is the second direction.

  A concave / convex pattern 8 is formed on the reflected light outgoing surface 5 a of the light guide member 5. The concavo-convex pattern 8 is configured by continuously forming convex portions 9, 9,... Projecting forward and extending in the left-right direction as the second direction in the vertical direction as the first direction. The concavo-convex pattern 8 has a function of guiding the light emitted from the light source units 7, 7,... And incident on the light guide member 5 to the reflection member 4 side by internal reflection.

The convex portions 9, 9,... According to the first modified comparative example have a cross-sectional shape parallel to the light incident surface 5b, for example, a parabolic shape (see FIG. 5). In other words, a line segment in the first direction connecting both ends 9a, 9a in the first direction of the convex portion 9 is defined as an X axis, and a line segment extending in the thickness direction through the midpoint 9b of both ends 9a, 9a of the convex portion 9 is defined. The outer shape of the convex portion 9 satisfies Y = −X ² / 4a + a, where Y is the maximum height of the convex portion 9 (height from the X axis).

  The optical sheet 6 is disposed between the light guide member 5 and the display panel 2 and has a function of diffusing light emitted from the reflected light output surface 5a of the light guide member 5, for example. The optical sheet 6 needs to have sufficient diffusibility to eliminate the directivity of light emitted from the light guide member 5 and have a low light absorption rate.

  The light source units 7, 7,... Are arranged in a state of facing the light incident surfaces 5b, 5b of the light guide member 5, respectively, and a plurality of light source units are arranged in the first direction (see FIGS. 2 and 3).

  The light source unit 7 includes a substrate 10 and a plurality of light emitting elements 11, 11,... Mounted on the substrate 10, and the light emitting elements 11, 11,. (See FIG. 4). As the light emitting elements 11, 11,..., For example, a light emitting diode (LED), an electroluminescence element, or the like is used.

  For example, eight light source units 7, 7,... Are arranged side by side on both sides of the light guide member 5 (see FIGS. 2 and 3). The light source units 7, 7,... Are individually controlled by a drive circuit (not shown), and when all are turned on, light is emitted from the entire region of the light guide member 5 toward the display panel 2 (FIG. 2). reference). In addition, the light source units 7, 7,... Are sequentially controlled to be lit in the arrangement direction (first direction), and light is emitted from each of the strip-like divided areas (the divided areas 1 to 8) of the light guide member 5. Light can be emitted toward the display panel 2 (see FIG. 3), and the light emitting device 3 can function as a so-called scan backlight. Such a function as a scan backlight is executed when the light source units 7, 7,... Are sequentially controlled to be turned on in accordance with the timing at which the pixel rows are sequentially rewritten on the display panel 2.

  FIG. 3 shows an example in which the light guide member 5 is divided into eight regions in the first direction to form the divided regions 1 to 8 in order from the upper side, and is positioned third from the upper side. The light source units 7 and 7 are controlled to be in a lighting state, and light is emitted from the third divided region 3 from the upper side.

[Optical path in light emitting device]
In the light emitting device 3 configured as described above, when light is emitted from the light emitting elements 11, 11,... Of the light source units 7, 7,. The light enters the light guide member 5 and is guided in the second direction inside the light guide member 5 and is internally reflected by the concave / convex pattern 8 of the light guide member 5. The light internally reflected by the uneven pattern 8 is transmitted through the light control surface 5 c of the light guide member 5 or is internally reflected by the light control surface 5 c of the light guide member 5.

  The light transmitted through the light control surface 5c of the light guide member 5 is reflected by the reflection surface 4a of the reflection member 4, is again incident on the light guide member 5 from the light control surface 5c, is emitted from the reflection / output surface 5a, and is guided. The light internally reflected by the light control surface 5c of the optical member 5 is emitted from the reflected light output surface 5a.

  The light emitted from the reflected light exit surface 5 a of the light guide member 5 is diffused by the optical sheet 6 and directed to the display panel 2 as a backlight and emitted from the display panel 2 as image light.

[Control of light in light guide member]
Below, the control of the light in the light guide member 5 performed in the light-emitting device 3 is demonstrated (refer FIG. 6 thru | or FIG. 11).

  FIG. 6 is a conceptual diagram showing the light emitting elements 11, 11, the light guide member 5, and the reflection member 4 as viewed from the light incident surface 5 b side of the light guide member 5. The interval between the centers of the light emitting elements 11 and 11 is L, and the thickness of the light guide member 5 is t. In addition, a line segment P projected from the light emitting element 11 to the reflected light emitting surface 5a on a plane parallel to the light incident surface 5b and a line segment extending from the center point of the light emitting element 11 toward the reflected light emitting surface 5a in the thickness direction. An angle formed by Q is an incident angle φ of light with respect to the reflected light emitting surface 5 a emitted from the light emitting element 11. Furthermore, θ is the maximum angle range that the reflected light can take when light incident at an incident angle φ is internally reflected by the reflected light exit surface 5a, and the reflection point of the reflected light on the reflected light exit surface 5a in the angle range θ. A range on the side approaching the light emitting element 11 from which light is emitted with reference to a line segment S passing through R in the thickness direction is negative, and a range on the far side is positive.

At this time, in the light emitting device 3, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases, and the angle range θ is positive. It covers both the range and the negative range. Such light control is performed by forming the convex portions 9, 9,... Of the concave-convex pattern 8 into a predetermined shape.

7 to 10, the incident angle φ is different in the optical path when the light emitted from the light emitting element 11 is internally reflected by the convex portion 9 in the range of 0 <φ <tan ⁻¹ (L / t). It is a figure shown about a case. In each figure, a dotted line indicates a light path from the light emitting element 11 to the convex portion 9, and a solid line indicates a light path internally reflected by the convex portion 9.

  7 shows an optical path when the incident angle φ is 0 °, FIG. 8 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG. 7, and FIG. 9 shows an incident angle φ of FIG. FIG. 10 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG. 9.

As shown in FIGS. 7 to 10, in the uneven pattern 8 of the light emitting device 3, the value of the angle range θ increases as the value of the incident angle φ increases in the range of 0 <φ <tan ⁻¹ (L / t). It can be seen that the angle range θ extends over both the positive range and the negative range.

Moreover, the convex part 9 is
Y = −X ² / 4a + a is satisfied, and as shown in FIG. 11, the light that is internally reflected by the convex portion 9 through the focal point V of the convex portion 9 is either a light guide member. 5 in the thickness direction.

< Second modified comparative example >
Next, an uneven pattern 8A according to a second modification comparative example will be described (see FIGS. 12 and 13).

  The concavo-convex pattern 8A is configured by projecting forward and projecting portions 9A, 9A,... Extending in the left-right direction as the second direction are continuously formed in the up-down direction as the first direction. The concavo-convex pattern 8 </ b> A has a function of guiding the light emitted from the light source units 7, 7,.

  The convex portions 9A, 9A,... Are formed such that the outer shape in the cross-sectional shape parallel to the light incident surface 5b is, for example, a shape in which two arcs are continuous, and the center point in the first direction is located at the foremost position. Has been.

Also in the concavo-convex pattern 8A, as in the concavo-convex pattern 8, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases, and the angle The range θ spans both the positive range and the negative range.

12 and 13 show the cases where the incident angles of the light paths when the light emitted from the light emitting element 11 is internally reflected by the convex portion 9A are different in the range of 0 <φ <tan ⁻¹ (L / t). It is a figure shown about. In each figure, a dotted line indicates a light path from the light emitting element 11 to the convex portion 9A, and a solid line indicates a light path internally reflected by the convex portion 9A.

  12 shows an optical path when the incident angle φ is small, and FIG. 13 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 12 and 13, in the uneven pattern 8A of the light emitting device 3, the value of the angle range θ increases as the value of the incident angle φ increases in the range of 0 <φ <tan ⁻¹ (L / t). It can be seen that the angle range θ extends over both the positive range and the negative range.

< Invention of this application >
Next, the concave / convex pattern 8B according to the present invention will be described (see FIGS. 14 and 15).

  The concavo-convex pattern 8B is configured by continuously forming convex portions 9B, 9B,... Projecting forward and extending in the left-right direction as the second direction in the vertical direction as the first direction. The concavo-convex pattern 8B has a function of guiding the light emitted from the light source units 7, 7,... And entering the light guide member 5 to the reflection member 4 side by internally reflecting the light.

The convex portions 9B, 9B,... Are formed in a shape in which the outer shape in a cross-sectional shape parallel to the light incident surface 5b is formed in a shape in which two arcs are continuous, and has a minute concave portion in the central portion in the first direction. Is formed. The radius of curvature of the arc of the convex portion 9B is made smaller than the radius of curvature of the arc of the convex portion 9A of the convex / concave pattern 8A according to the second modification comparative example .

In the concavo-convex pattern 8B, as in the concavo-convex pattern 8 and the concavo-convex pattern 8A, the value of the angle range θ decreases as the incident angle φ increases in the range of 0 <φ <tan ⁻¹ (L / t). In addition, the angle range θ spans both the positive range and the negative range.

14 and 15 show cases where the incident angles of the light paths when the light emitted from the light emitting element 11 is internally reflected by the convex portion 9B are different within the range of 0 <φ <tan ⁻¹ (L / t). It is a figure shown about. In each figure, a dotted line indicates a light path from the light emitting element 11 to the convex portion 9B, and a solid line indicates a light path internally reflected by the convex portion 9B.

  FIG. 14 shows an optical path when the incident angle φ is small, and FIG. 15 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 14 and 15, in the uneven pattern 8B of the light emitting device 3, the value of the angle range θ increases as the value of the incident angle φ increases in the range of 0 <φ <tan ⁻¹ (L / t). It can be seen that the angle range θ extends over both the positive range and the negative range.

<Comparative example>
Next, the surface shape (unevenness pattern) of the light guide member according to the comparative example (conventional example) will be described (see FIGS. 16 to 25).

  The shape 50A according to the first comparative example has a light incident surface formed in a flat shape (see FIGS. 16 and 17).

FIGS. 16 and 17 show the optical paths when the light emitted from the light emitting element is internally reflected by the shape 50A in the range of 0 <φ <tan ⁻¹ (L / t), with different incident angles. FIG. In each figure, a dotted line indicates a light path from the light emitting element to the shape 50A, and a solid line indicates a light path internally reflected by the shape 50A.

  16 shows an optical path when the incident angle φ is small, and FIG. 17 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 16 and 17, in the shape 50A, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ increases as the incident angle φ increases, and the angle It can be seen that the range θ does not extend over both the positive range and the negative range.

  The concavo-convex pattern 50B according to the second comparative example is formed with projections 51B, 51B,... Projecting forward and extending in the left-right direction, which is the second direction, continuously in the vertical direction, which is the first direction. (See FIGS. 18 and 19).

  As for convex part 51B, 51B, ..., the outer shape in the cross-sectional shape parallel to a light-incidence surface is formed in the triangle shape.

18 and 19 show cases where the incident angles of the light paths when the light emitted from the light emitting element is internally reflected by the convex portion 51B are different in the range of 0 <φ <tan ⁻¹ (L / t). FIG. In each figure, a dotted line indicates a light path from the light emitting element to the convex portion 51B, and a solid line indicates a light path internally reflected by the convex portion 51B.

  18 shows an optical path when the incident angle φ is small, and FIG. 19 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 18 and 19, in the concavo-convex pattern 50B, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases. It can be seen that the angle range θ does not extend over both the positive range and the negative range.

  In the uneven pattern 50C according to the third comparative example, convex portions 51C, 51C,... Projecting forward and extending in the left-right direction as the second direction are continuously formed in the up-down direction as the first direction. (See FIGS. 20 and 21).

  The convex portions 51C, 51C,... Are formed in an arc shape whose outer shape in a cross-sectional shape parallel to the light incident surface is convex forward.

20 and FIG. 21, in the range of 0 <φ <tan ⁻¹ (L / t), the light paths emitted from the light emitting element are reflected on the inner surface by the convex portions 51C and the incident angles are different from each other. FIG. In each figure, a dotted line indicates a light path from the light emitting element to the convex portion 51C, and a solid line indicates a light path internally reflected by the convex portion 51C.

  20 shows an optical path when the incident angle φ is small, and FIG. 21 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 20 and 21, in the concavo-convex pattern 50C, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases. It can be seen that as the value of the incident angle φ increases, the angle range θ does not extend over both the positive range and the negative range.

  The concavo-convex pattern 50D according to the fourth comparative example is formed with projections 51D, 51D,... That protrude forward and extend in the left-right direction, which is the second direction, continuously in the vertical direction, which is the first direction. (See FIGS. 22 and 23).

  The convex portions 51D, 51D,... Are formed in a circular arc shape whose outer shape in a cross-sectional shape parallel to the light incident surface is convex forward. The radius of curvature of the arc of the convex portion 51D is made smaller than the radius of curvature of the arc of the convex portion 51C of the convex / concave pattern 50C according to the third comparative example.

22 and 23 show cases where the incident angles of the light paths when the light emitted from the light emitting element is internally reflected by the convex portion 51D are different in the range of 0 <φ <tan ⁻¹ (L / t). FIG. In each figure, a dotted line indicates a light path from the light emitting element to the convex part 51D, and a solid line indicates a light path internally reflected by the convex part 51D.

  22 shows an optical path when the incident angle φ is small, and FIG. 23 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 22 and 23, in the concavo-convex pattern 50D, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases. It can be seen that as the value of the incident angle φ increases, the angle range θ does not extend over both the positive range and the negative range.

  The concave / convex pattern 50E according to the fifth comparative example is configured by continuously forming concave portions 51E, 51E,... Extending in the left-right direction as the second direction in the vertical direction as the first direction. (See FIGS. 24 and 25).

  The recesses 51E, 51E,... Are formed in a circular arc shape whose outer shape in a cross-sectional shape parallel to the light incident surface is recessed forward.

24 and 25 show the optical paths when the light emitted from the light emitting element is internally reflected by the recess 51E in the range of 0 <φ <tan ⁻¹ (L / t), with different incident angles. FIG. In each figure, the dotted line indicates the path of light reaching the recess 51E from the light emitting element, and the solid line indicates the path of light internally reflected by the recess 51E.

  24 shows an optical path when the incident angle φ is small, and FIG. 25 shows an optical path when the incident angle φ is larger than the incident angle φ of FIG.

As shown in FIGS. 24 and 25, in the concavo-convex pattern 50E, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases. It can be seen that as the value of the incident angle φ increases, the angle range θ does not extend over both the positive range and the negative range.

< Third modified comparative example >
Next, an uneven pattern 8C according to a third modified comparative example will be described (see FIG. 26).

  The concavo-convex pattern 8 </ b> C is configured by continuously forming convex portions 9 </ b> C, 9 </ b> C,... Projecting forward and extending in the left-right direction as the second direction in the vertical direction as the first direction. The concavo-convex pattern 8 </ b> C has a function of guiding the light emitted from the light source units 7, 7,.

As for convex part 9C, 9C, ..., the outer shape in the section parallel to light entrance surface 5b is formed in the shape of a parabola, for example. That is, like the convex part 9,
Y = −X ² / 4a + a is satisfied.

In the concavo-convex pattern 8C, in the range from the light incident surfaces 5b and 5b of the light guide member 5 to the distance L2 in the second direction, the incident angle φ is in the range of 0 <φ <tan ⁻¹ (L / t). As the value increases, the value of the angle range θ decreases, and the angle range θ extends over both the positive range and the negative range.

Further, in the concavo-convex pattern 8C, in a range away from the light incident surfaces 5b and 5b of the light guide member 5 from the distance L2 in the second direction, in a range of 0 <φ <tan ⁻¹ (L / t), As the value of the incident angle φ increases, the value of the angle range θ decreases, and when φ = tan ⁻¹ (L / t), the angle range θ becomes only a negative range.

However, L2> L / [tan {sin ⁻¹ (1 / n)}], L is the distance between the centers of the light emitting elements 11, 11, and n is the refractive index of the light guide member 5.

  The distance L2 is 50 mm, for example. The convex portion 9C is formed in the same shape as the convex portion 9 in the range from the light incident surfaces 5b and 5b to the distance L2, and in the range away from the distance L2, for example, the same shape as the concave / convex pattern 50B or the concave / convex pattern 50D. Is formed.

As described above, the convex portion 9C is
Since Y = −X ² / 4a + a is satisfied, the light that is internally reflected by the convex portion 9C through the focal point V of the convex portion 9C travels in the thickness direction of the light guide member 5. Is done.

<Comparison data>
Below, the data measured regarding the uneven | corrugated pattern 8, 8A, 8B, 8C and the shape 50A and the uneven | corrugated pattern 50B, 50C, 50D which concern on a comparative example are demonstrated (refer FIG. 27 thru | or FIG. 35).

  FIG. 27 is a graph showing data obtained by measuring illuminance at a position where the distance in the second direction from the light incident surface 5b in the light guide member 5 is 10.5 mm. The measurement of the data in FIG. 27 was performed in a state where light was emitted from five light emitting elements 11, 11,... That had an interval L of 14.64 mm and were separated in the first direction.

  The horizontal axis indicates the position in the first direction with respect to the light emitting element 11, and the light emitting point of the third light emitting element 11 among the five light emitting elements 11, 11,. The vertical axis indicates the illuminance ratio, and the illuminance at the position where the distance is 0 in the concavo-convex pattern 8 is the reference illuminance “1”.

  As shown in FIG. 27, the unevenness patterns 8, 8A, 8B, and 8C have almost no luminance unevenness, but in the shape 50A and the uneven patterns 50B, 50C, and 50D, the difference between the maximum value and the minimum value is large and large. It can be seen that uneven brightness occurs.

  FIG. 28 is a graph showing data obtained by measuring illuminance at a position where the distance in the second direction from the light incident surface 5b in the light guide member 5 is 8.5 mm. In the measurement of the data in FIG. 28, in the same manner as the measurement in FIG. 27, the light is emitted from the five light emitting elements 11, 11,... It was conducted.

  The horizontal axis indicates the position in the first direction with respect to the light emitting element 11, and the light emitting point of the third light emitting element 11 among the five light emitting elements 11, 11,. The vertical axis indicates the illuminance ratio, and the illuminance at the position where the distance is 0 in the concavo-convex pattern 8 is the reference illuminance “1”.

  FIG. 28 shows, as an example, data measured for the concave / convex pattern 8 and the shape 50A, the concave / convex patterns 50B, 50C, and 50D according to the comparative example.

  As shown in FIG. 28, in the uneven pattern 8, the difference between the maximum value and the minimum value is small and the luminance unevenness is small, but in the shape 50A and the uneven patterns 50B, 50C, and 50D, the difference between the maximum value and the minimum value is large. It can be seen that unevenness has occurred. In particular, the luminance unevenness in the shape 50A and the uneven pattern 50C is large.

  FIG. 29 is a graph showing data obtained by measuring the illuminance at the position where the distance in the second direction from the light incident surface 5b in the light guide member 5 is 12.5 mm. In the measurement of the data shown in FIG. 29, light is emitted from the five light emitting elements 11, 11,... Spaced apart in the first direction with the distance L being 14.64 mm, as in the measurements of FIGS. Made in the state.

  The horizontal axis indicates the position in the first direction with respect to the light emitting element 11, and the light emitting point of the third light emitting element 11 among the five light emitting elements 11, 11,. The vertical axis indicates the illuminance ratio, and the illuminance at the position where the distance is 0 in the concavo-convex pattern 8 is the reference illuminance “1”.

  FIG. 29 shows, as an example, data measured for the concave / convex pattern 8 and the shape 50A, the concave / convex patterns 50B, 50C, and 50D according to the comparative example.

  As shown in FIG. 29, the unevenness pattern 8 has almost no luminance unevenness, but the shape 50A and the unevenness patterns 50B and 50D have a large difference in brightness between the maximum and minimum values. I understand.

  FIG. 30 shows the divided regions 1 to 8 when light is emitted from the light emitting elements 11, 11,... Of the light source units 7, 7 positioned corresponding to the divided region 1 in the light guide member 5. It is a graph which shows the data which measured the illumination intensity. The horizontal axis indicates the divided area, the vertical axis indicates the illuminance ratio, and the maximum illuminance in the divided area 1 of the uneven pattern 8 is the reference illuminance “1”.

  FIG. 31 is an enlarged graph showing a portion with a low illuminance ratio in the graph of FIG.

  30 and 31 show, as an example, data measured for the concave / convex pattern 8 and the shape 50A, the concave / convex patterns 50B, 50C, and 50D according to the comparative example.

  As shown in FIGS. 30 and 31, the uneven pattern 8 has a small amount of light leakage to areas other than the divided area 1, and the shape 50 </ b> A and the uneven pattern 50 </ b> C has a large amount of light leakage to areas other than the divided area 1. I understand.

  FIG. 32 shows the divided regions 1 to 8 when light is emitted from the light emitting elements 11, 11,... Of the light source units 7, 7 positioned corresponding to the divided region 1 in the light guide member 5. It is a graph which shows the data which measured the illumination intensity.

  FIG. 32 shows, as an example, data measured with respect to the concave / convex pattern 8 and the concave / convex pattern 8C, respectively, for the central position of the light guide member 5 and the position near the light incident surface 5b in the second direction. The horizontal axis indicates the divided area, the vertical axis indicates the illuminance ratio, and the maximum illuminance in the divided area 1 of the uneven pattern 8 is the reference illuminance “1”.

  As shown in FIG. 32, in the uneven pattern 8C, the difference between the illuminance at the center position of the light guide member 5 and the illuminance at the position near the light incident surface 5b is smaller than that of the uneven pattern 8.

  FIG. 33 is a graph showing data obtained by measuring illuminance at a position where the distance from the light incident surface 5b in the second direction in the light guide member 5 is 5 mm. FIG. 34 is a graph showing data obtained by measuring illuminance at a position where the distance from the light incident surface 5b in the second direction in the light guide member 5 is 7 mm. FIG. 35 is a graph showing data obtained by measuring illuminance at a position where the distance from the light incident surface 5b in the second direction in the light guide member 5 is 9 mm.

  33 to 35 show, as an example, data measured for the uneven pattern 8 and the shape 50A and the uneven pattern 50B according to the comparative example. 33 to 35 were measured in a state where light was emitted from five light emitting elements 11, 11,... Separated in the first direction.

  The horizontal axis indicates the position in the first direction with respect to the light emitting element 11, and the light emitting point of the third light emitting element 11 among the five light emitting elements 11, 11,. The vertical axis represents the illuminance.

  As shown in FIG. 33 to FIG. 35, the unevenness in the uneven pattern 8 is greatly reduced in luminance unevenness as the distance from the light incident surface 5b increases. However, in the shape 50A and the uneven pattern 50B, the distance from the light incident surface 5b is reduced. Even if it becomes larger, it is in a situation where uneven brightness tends to occur. In particular, in the concavo-convex pattern 50B, large luminance unevenness occurs even when the distance from the light incident surface 5b increases.

<Summary>
As described above, in the light emitting device 3, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases, and The angle range θ extends over both the positive range and the negative range.

  Since the value of the incident angle φ is small in the region near the light emitting element 11 in the light guide member 5, the value of the angle range θ decreases as the value of the incident angle φ increases, so that the light reaches strong light. It is possible to reflect toward a wide area in the first direction including a portion between the light emitting elements 11 and 11 in the light guide member 5 which is difficult. In addition, since the value of the incident angle φ is large in the region between the light emitting elements 11 and 11 of the light guide member 5, the value of the angle range θ decreases as the value of the incident angle φ increases, so that weak light is guided. It is possible to efficiently reflect toward the portion between the light emitting elements 11 and 11 in the optical member 5.

  On the other hand, if the angle range θ is only a positive range, the amount of light leaked to other divided areas increases, and if the angle range θ is only a negative range, the light leaked to other divided areas is reduced. However, it becomes difficult for light to reach the region between the light emitting elements 11 and 11 in the vicinity of the light incident surface 5 b of the light guide member 5.

Therefore, in the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases, and the angle range θ is between a positive range and a negative range. By extending over both ranges, luminance unevenness in the light guide member 5 can be reduced, and uniformity of luminance can be improved and leakage light to other divided regions can be reduced. .

Moreover, the outer shape of the convex parts 9 and 9C is
Since it is formed in a parabolic shape that satisfies Y = −X ² / 4a + a, the light that is internally reflected through the focal points V of the convex portions 9 and 9C travels in the thickness direction of the light guide member 5.

  Accordingly, it is possible to further reduce luminance unevenness and further reduce light leaked to other divided regions.

Furthermore, in the concavo-convex pattern 8C, in the range from the light incident surfaces 5b and 5b to the distance L2 in the second direction, the value of the incident angle φ is in the range of 0 <φ <tan ⁻¹ (L / t). As the value increases, the value of the angle range θ decreases, and the angle range θ extends over both the positive range and the negative range. Also, in the range of 0 <φ <tan ⁻¹ (L / t) in the range away from the distance L2 in the second direction from the light incident surfaces 5b and 5b of the light guide member 5, the value of the incident angle φ is As the value increases, the value of the angle range θ decreases, and when φ = tan ⁻¹ (L / t), the angle range θ is set to a negative range only.

However, L2> L / [tan {sin ⁻¹ (1 / n)}], L is the distance between the centers of the light emitting elements 11, 11, and n is the refractive index of the light guide member 5.

  Therefore, even if the shape of the concavo-convex pattern changes, the luminance unevenness in the light guide member 5 can be reduced, the uniformity of luminance can be improved, and the leakage light to other divided regions can be reduced, In addition, the degree of freedom in designing the concavo-convex pattern can be improved.

The specific shapes and structures of the respective parts shown in the embodiments for carrying out the invention described above are merely examples of the embodiments in carrying out the present invention, and the technology of the present invention is thereby limited. The scope should not be interpreted in a limited way.

  DESCRIPTION OF SYMBOLS 3 ... Light-emitting device, 4 ... Reflection member, 5 ... Light guide member, 5a ... Reflection light emission surface, 5b ... Light-incidence surface, 11 ... Light-emitting element, 8B ... Uneven pattern, 9B ... Convex part

Claims (1)

A plate in which one surface in the thickness direction is formed as a reflected light emitting surface on which light is internally reflected and emitted, and both side surfaces facing the direction perpendicular to the thickness direction are formed as light incident surfaces on which light is incident. A light guide member,
A plurality of light emitting elements that are arranged to face the light incident surface of the light guide member and are spaced apart in a first direction perpendicular to the thickness direction;
The light guide member is disposed so as to face the surface opposite to the reflected light exit surface, reflects light that is reflected from the reflected light exit surface and transmitted through the light guide member, and is guided from the opposite surface. A reflective member for entering the optical member,
A plurality of light beams emitted from the light emitting element are internally reflected on the light emitting surface of the light guide member extending in a second direction that is continuous in the first direction and orthogonal to both the thickness direction and the first direction. A concavo-convex pattern composed of convex portions is formed,
The interval between the light emitting elements is L, the thickness of the light guide member is t, and the optical path from the light emitting element to the reflected light emitting surface is projected onto a plane parallel to the light incident surface and the center of the light emitting element. An angle formed by a line segment extending from the point to the reflected light exit surface side in the thickness direction is an incident angle φ of light with respect to the reflected light exit surface, and light incident at the incident angle φ is internally reflected by the reflected light exit surface. The maximum angle range that the reflected light can take is θ, and the range closer to the light emitting element from which light is emitted with reference to the line segment extending in the thickness direction of the angle range θ is negative and the light emission When the range on the side away from the element is positive,
In the range of 0 <φ <tan ⁻¹ (L / t), the value of the angle range θ decreases as the value of the incident angle φ increases, and the angle range θ decreases from the positive range to the negative range. It is to span both the range of the range,
The light emitting device, wherein the convex portion is formed in a shape in which an outer shape in a cross-sectional shape parallel to the light incident surface is a shape in which two arcs are continuous and has a concave portion in a central portion in the first direction .

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