JP2016219156A - Luminaire - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a luminaire capable of further enhancing an optical added value.SOLUTION: A luminaire includes: a device body 3 having a light source part 11 and a mounting part 13 on which the light source part 11 is mounted; and a translucent cover 5 for covering the light source part 11. The translucent cover 5 is constituted by a plurality of different light diffusion regions 155, 157, 159 being combined independently, and when the translucent cover 5 is viewed toward the side to which the light is emitted from the light source part 11, a first light diffusion region 155 exists in the central part, and the second light diffusion region 157 exists on the outside peripheral part of the first light diffusion region 155.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an illumination device in which a light source part is covered with a translucent cover.

An illumination device in which a light source part is covered with a translucent cover is used by being installed on an installation surface such as a ceiling or a wall. An illuminating device that illuminates the side opposite to the installation surface and has recently been optically enhanced in value added has been proposed (for example, Patent Document 1).
In Patent Document 1, a plurality of light-emitting elements mounted on a substrate, a region having a relatively small transmittance of light emitted from the light-emitting device, and a region having a relatively large light transmittance are mixed. There is disclosed an illuminating device including a shade provided with a formed light transmission control means and an optical control member provided between the light emitting element and the shade.
With this configuration, the glare is controlled to enhance the effect, and the added value as a lighting device can be increased.

JP 2014-49275 A

The shade of the above configuration has a problem that the effect of production is small because a region with low light transmittance and a region with high light transmittance are mixed.
In view of the above problems, an object of the present invention is to provide an illuminating device that can further increase the optical added value.

  An illuminating device according to the present invention is an illuminating device including a device main body having a light source unit and a mounting unit on which the light source unit is mounted, and a translucent cover that covers the light source unit. A plurality of different light diffusion regions are independently combined, and the first light diffusion region is present at the center when the light-transmitting cover is viewed toward the light emission side from the light source unit. In addition, the second light diffusion region exists in the outer peripheral portion of the first light diffusion region.

  According to the said structure, since a translucent cover is independently provided with a several different light-diffusion area | region, added value can be optically raised.

It is an external appearance perspective view from the front of the ceiling light of a 1st embodiment. It is sectional drawing of the ceiling light of 1st Embodiment. It is a disassembled perspective view of the ceiling light of 1st Embodiment. It is the figure which looked at the state which removed a part of protective cover of the main part of a device of a 1st embodiment from the front. It is the perspective view which looked at the adapter of a 1st embodiment from back. It is a cross-sectional enlarged view of the center part of the apparatus main body of 1st Embodiment. It is a perspective view of the locking tool of 1st Embodiment. It is the perspective view which looked at the attachment cover of 1st Embodiment from back. It is an attachment cover sectional view of a 1st embodiment. It is the enlarged view which looked at the attachment cover of 1st Embodiment from back. It is the perspective view which looked at the main cover of 1st Embodiment from the front. It is a disassembled perspective view of the main cover of 1st Embodiment. It is sectional drawing of the main cover of 1st Embodiment. It is the enlarged view which looked at the intermediate main cover of 1st Embodiment from back. It is the external appearance perspective view which looked at the ceiling light of 2nd Embodiment from the front. It is a disassembled perspective view of the ceiling light of 2nd Embodiment. It is the perspective view which looked at the attachment cover of 2nd Embodiment from the front. It is the perspective view which looked at the attachment cover of 2nd Embodiment from back. It is sectional drawing of the ceiling light for demonstrating the positional relationship of LED and a 2nd light-diffusion area | region.

<Overview>
An illuminating device according to one embodiment of the present invention is an illuminating device including a device main body including a light source unit and a mounting unit on which the light source unit is mounted, and a translucent cover that covers the light source unit. The cover is configured by independently combining a plurality of different light diffusion regions, and the first light diffusion region is centered when the light-transmitting cover is viewed toward the side from which light is emitted from the light source unit. And the second light diffusion region exists in the outer peripheral portion of the first light diffusion region.
In the illumination device according to another aspect, the second light diffusion region is lower in light diffusibility than the first light diffusion region. Thereby, the luminous intensity of the light emitted from the second light diffusion region becomes higher than the luminous intensity of the light emitted from the first light diffusion region, and the effect can be improved.
In the illumination device according to another aspect, the main surface of the second light diffusion region has a diamond cut pattern. Thereby, the feeling of glitter of the light emitted from the second light diffusion region can be improved.

In the illumination device according to another aspect, the main surface of the second light diffusion region is a surface facing the light source unit. Thereby, the light emitted from the light source unit directly reaches the second light diffusion region, and the effect of production can be enhanced.
In the illumination device according to another aspect, a third light diffusion region exists in an outer peripheral portion of the second light diffusion region. Thereby, design property can be improved.
In the illumination device according to another aspect, the light diffusibility of the third light diffusion region is the same as the light diffusion property of the first light diffusion region, and the light transmittance of the third light diffusion region is the first light diffusion. It is the same as the light transmittance of the region. Thereby, a translucent cover can be prepared at low cost.
In the illumination device according to another aspect, the second light diffusion region exists in a ring shape when the translucent cover is viewed toward a side where light is emitted from the light source unit. Thereby, the designability can be improved.

<First Embodiment>
Hereinafter, a lighting device which is one embodiment of the present invention will be described in detail with reference to the drawings. Here, a ceiling light will be described as an example of a lighting device.

1. Whole structure of ceiling light It demonstrates using FIG.1 and FIG.2.
The ceiling light 1 is used by being detachably attached to an attached member 4 provided on an installation surface 2 such as a ceiling via an adapter 6. The ceiling light 1 includes an apparatus main body 3 and a translucent cover 5 that is detachably attached to the apparatus main body 3. The translucent cover 5 covers the side opposite to the installation surface 2 in the apparatus main body 3.
The side from which light is emitted from the ceiling light 1 is defined as the front side or the front side. Examples of the attached member 4 include a rosette and a hook ceiling.
The ceiling light 1 has, for example, a light control function, a color control function, a timer function, and the like, and provides a light environment selected by a signal from a remote controller (not shown).

2. Device Main Body The device main body 3 will be described with reference to FIGS.
The apparatus body 3 includes a light source unit 11 composed of a plurality of LEDs 21, a circuit unit 12 for lighting the light source unit 11, a mounting unit 13 for mounting the light source unit 11, an attachment unit 14 attached to the adapter 6, At least a cover mounting part 15 for mounting the translucent cover 5 is provided.
In addition to the above configuration, the apparatus main body 3 includes, for example, a light source cover part 17 that covers the light source part 11, a circuit accommodating part 18 that accommodates the circuit part 12, a receiving part 19 that receives an operation signal from a remote controller (not shown), and the like. May be.
Hereinafter, each part will be described.

(1) Light source part The light source part 11 is demonstrated mainly using FIG.3 and FIG.4.
The light source unit 11 includes a plurality of (for example, 96) LEDs 21 and one or a plurality of (for example, eight) mounting substrates 23 for mounting the plurality of LEDs 21. Since the plurality of LEDs 21 have a toning function, they have a plurality of types having different light colors (for example, there are two types of light colors: a light bulb color and a daylight color).

The mounting position of the LED 21 may be regular or may not be regular. Examples of the regular shape include a linear shape (including one row and a plurality of rows), a staggered shape, an arc shape (including a single row and a plurality of rows), and the like.
The plurality of mounting boards 23 are arranged in an annular shape surrounding the central opening 37 of the mounting portion 13. Twelve LEDs 21 on one mounting board 23 are mounted in a plurality so that 96 LEDs 21 form a triple ring as a whole.

(2) Circuit Unit The circuit unit 12 will be described mainly with reference to FIGS.
The circuit unit 12 includes a plurality of electronic components 25, 27, and 29, and one or a plurality of (for example, one) circuit board 33 for mounting the plurality of electronic components 25, 27, and 29. Have In addition, the code | symbol is attached | subjected to three electronic components among several electronic components.
A plurality of electronic components 25, 27, 29 constitute, for example, a rectifier circuit, a smoothing circuit, a voltage conversion circuit, and the like. The plurality of electronic components include an IC component that controls the lighting of the LED 21 by a signal received from the remote controller.
Since the adapter 6 is disposed at the center of the circuit housing portion 18, the circuit board 33 has, for example, an arc shape. The circuit board 33 is fixed to the circuit housing portion 18 in a state of being arranged around the adapter 6.

(3) Mounting Unit The mounting unit 13 will be described mainly with reference to FIGS.
The mounting portion 13 is configured by a base member 35. The base member 35 has a plate shape having an opening 37 at the center. The adapter 6 is fitted in the opening 37.
Although the general shape of the base member 35 is circular when viewed from the floor (front side), the external shape may be other shapes such as a square and a rectangle, for example.

The mounting part 13 has screw holes and through holes in the base member 35 for fixing the light source part 11, the cover mounting part 15, the light source cover part 17, the circuit housing part 18, and the receiving part 19 to the base member 35. .
The mounting unit 13 has a light source unit mounting region 41 for mounting the light source unit 11 on the surface of the base member 35 and around the opening 37. A plurality of mounting boards 23 are fixed to the light source portion mounting area 41 by a screw body, a pin body, or the like in a state of being arranged in an annular shape surrounding the opening 37.
The mounting part 13 has a screw hole or a through hole for fixing the light source cover part 17 on the surface of the base member 35 and outside the light source part mounting area 41, and the cover mounting part 15 outside the light source part mounting area 41. Is provided.

  The mounting portion 13 has a circuit portion mounting area for providing the circuit portion 12 on the back surface of the base member 35 and around the opening 37. Note that the circuit portion 12 is mounted on the mounting portion 13 by attaching the circuit housing portion 18 to which the circuit board 33 is fixed to the base member 35 by the screw body 87.

(4) Attachment part The attachment part 14 is demonstrated mainly using FIG.3 and FIG.6.
The mounting portion 14 includes a disc-like portion 45 having an opening 43 as a center, and an outer cylinder portion 47 and an inner cylinder portion that protrude from the disc-like portion 45 forward and in a double cylindrical shape at intervals from the opening 43. 49.
The attachment portion 14 is attached to the adapter 6 by engaging the engaging claw 53 (see FIG. 5) of the adapter 6 with the peripheral portion 45 a of the opening 43 on the surface of the disk-like portion 45.
The mounting portion 14 is configured such that the circuit housing portion 18 is connected to the circuit housing portion 18 by the screw body 87 in a state where the rear surface of the disk-like portion 45 is in contact with the circuit housing portion 18 and the front ends of the outer cylinder portion 47 and the inner cylinder portion 49 are in contact with the base member 35. Fixed to.

(5) Cover attachment part The cover attachment part 15 is demonstrated mainly using FIG.4 and FIG.7.
The cover mounting portion 15 is configured by a plurality of (for example, three) locking members 55 attached to the surface of the base member 35 at intervals along the outer peripheral edge of the base member 35.
The translucent cover 5 is attached when the translucent cover 5 is rotated with respect to the base member 35 in a predetermined direction (for example, clockwise) when the translucent cover 5 is rotated in a predetermined direction (for example, clockwise). 8) is performed by engaging the locking tool 55.
The locking member 55 has a U-shaped section 57 that has a U-shaped cross section orthogonal to the rotation direction of the translucent cover 5 and extends in the rotation direction, and a longitudinal direction of the U-shaped section 57. And a lid 59 that closes an end of the translucent cover 5 (on the traveling side in the rotational direction). The locking tool 55 is fixed to the base member 35 by a screw body 63 that passes through the bottom wall 57 a of the U-shaped portion 57.

(6) Light source cover part The light source cover part 17 is demonstrated mainly using FIGS. 2-4 and FIG.
The light source cover part 17 is comprised by the protective cover 65 which consists of a translucent resin material. The protective cover 65 covers a plurality of mounting boards 23 arranged in an annular shape as a whole from the front side. Here, the protective cover 65 includes a plurality of (for example, four) cover members 67. A plurality of (for example, n (n is a natural number)) cover members 67 have a shape in which a ring is 1 / n when viewed from the front side.

In the cross section, the cover member 67 includes a dome portion 67a having a central portion projecting in a dome shape toward the front side, an inner collar portion 67b projecting from the inner peripheral edge of the dome portion 67a toward the opening 37 side of the base member 35, and a dome. It has an outer flange portion 67c that projects from the outer peripheral edge of the portion 67a to the outer peripheral edge side of the base member 35.
The inner collar portion 67 b is pressed against the base member 35 by the receiving portion 19. The outer flange portion 67 c is fixed to the base member 35 by a screw body 69.

(7) Circuit housing portion The circuit housing portion 18 will be described mainly with reference to FIGS. 2, 3, and 6.
The circuit housing portion 18 is configured by a bottomed cylindrical member 77 having an opening 75 in the bottom portion 73. The circuit portion 12 is accommodated in the circuit accommodating portion 18 by fixing the circuit board 33 to the bottom portion 73 with the pin body 79 in a state where the electronic components 25, 27, and 29 are located on the base member 35 side.
The bottomed tubular member 77 has an outer flange portion 85 that projects outward from the front end of the tubular portion 83. The outer flange portion 85 is fixed to the back surface of the base member 35 with a screw body 87. A peripheral portion 73a of the opening 75 of the bottom portion 73 is recessed on the base member 35 side. The disc-like portion 45 of the attachment portion 14 is fixed to the peripheral portion 73a by the screw body 87.

(8) Receiving Unit The receiving unit 19 will be described mainly with reference to FIG. 3, FIG. 4, and FIG.
The receiving unit 19 includes a housing 91 and a receiving sensor 93 provided in the housing 91. The casing 91 here has a night light 94 and a channel switch 96 in addition to the reception sensor 93.
The casing 91 includes a main body 95 having a bottomed cylindrical shape, and a lid 97 that closes an opening of the main body 95 so as to be freely opened and closed. The main body 95 includes a bottom wall 103 having an opening (through hole) 99 for the adapter 6, a cylindrical wall 105 extending forward from the outer peripheral edge of the bottom wall 103, and a center of the main body 95 from the front end of the cylindrical wall 105. It has a flange 107 that extends to the opposite side of the shaft and then bends rearward and then projects outward again.

The lid portion 97 has a bulging portion 109 that bulges to the front side, and a covering portion 113 that covers the bulging portion 109 from the back side. In the space between the bulging portion 109 and the covering portion 113, a receiving substrate 115 on which the receiving sensor 93, nightlight 94, and channel switch 96 are mounted is accommodated.
In the receiving part 19, the bottom wall 103 of the main body part 95 is fixed to the peripheral part of the opening 37 of the base member 35 by a screw body. In the fixed state, the rear end portion 107 a of the flange portion 107 of the housing 91 abuts against the inner flange portion 67 b of the cover member 67 from the front side, and the bottom wall 103 of the housing 91 contacts the peripheral portion of the opening 37 of the base member 35. Touch. The receiving unit 19 also has a function of covering the adapter 6 arranged in the central opening of the apparatus main body 3.

3. Translucent Cover The translucent cover 5 will be described with reference to FIGS. 1 to 3 and FIGS. 8 to 14.
The translucent cover 5 integrally includes an attachment cover 121 attached to the apparatus main body 3 and a main cover 123 attached to the attachment cover 121. The attachment cover 121 and the main cover 123 are made of, for example, a translucent resin material.

(1) Mounting cover The mounting cover 121 is demonstrated mainly using FIGS. 8-10.
The attachment cover 121 has an annular shape as a whole. The attachment cover 121 has an auxiliary portion 127 for attaching the main cover 123 to the apparatus main body 3. The mounting cover 121 has a decorative portion 129 in addition to the auxiliary portion 127.
The decorative portion 129 includes an annular portion 131 that extends substantially parallel to the installation surface 2 (for example, an annular shape) and an inclined portion 133 that extends from the outer peripheral edge of the annular portion 131 into a tubular shape that extends rearward. Have.

A predetermined pattern is provided on the back surface of the annular portion 131. Here, it is a diamond cut pattern 134. A predetermined pattern is also applied to the back surface of the inclined portion 133. Here, it is a vertical stripe pattern 135 extending in the radial direction.
The diamond cut pattern 134 includes an uneven shape having regularity in the circumferential direction of the annular portion 131. Concavities and convexities surround the triangles 134c and 134d divided by one diagonal line 134b in a plurality of squares 134a arranged in the circumferential direction of the annular portion 131 (the portions that are hatched upward in FIG. 10). It is configured by alternately repeating an ascending gradient and a descending gradient along the direction. The quadrangle 134a has a substantially rectangular shape with a long side in the radial direction.

  The diamond-cut pattern 134 includes a prism shape having regularity in the circumferential direction of the annular portion 131. As an example of the prism shape, more specifically, it has an irregular shape having regularity. The prism shape in plan view is one of two sides in which the inside of a plurality of quadrilaterals 134e (the portions that are hatched to the right in FIG. 10) arranged in the circumferential direction of the annular portion 131 extend in the circumferential direction. It is divided into five triangles 134g, 134h, 134i, 134j, and 134k with the apex 134f existing on the side as the apex angle, and triangles adjacent in the circumferential direction alternate with ascending and descending gradients along the circumferential direction. It has a repeating shape.

The diamond cut pattern 134 has quadrangles 134a and 134e arranged in the circumferential direction in a plurality of stages (for example, two stages) in the radial direction.
The vertical stripe pattern 135 has a quadrangle 135a having the same dimension as the side extending in the circumferential direction of the square 134a of the diamond cut pattern 134 in a state in which an upward gradient and a downward gradient are repeated in the circumferential direction.
The mounting cover 121 also has a light guide function of guiding the light incident from the auxiliary unit 127 out of the light emitted from the light source unit 11 through the decoration unit 129 and emitting it to the installation surface 2 side. At this time, light diffused (diffusely reflected) by the diamond cut pattern 134 of the annular portion 131 is emitted to the side opposite to the installation surface 2. Thereby, the optical added value of the ceiling light 1 can be increased by the light emission of the light source unit 11.

The auxiliary part 127 has a stepped cylindrical shape. The auxiliary portion 127 has a large-diameter cylindrical portion 137, a small-diameter cylindrical portion 139, and a connecting portion 141.
The auxiliary unit 127 has attached means for attaching to the apparatus main body 3 and attachment means for attaching the main cover 123.
The large-diameter cylindrical portion 137 has a concave portion 143 that engages with the convex portion 175 of the cylindrical portion 151 of the main cover 123. The concave portion 143 corresponds to the convex portion 175 of the cylindrical portion 151, and is recessed toward the decorative portion 129 at a portion spaced in the circumferential direction on the inner peripheral surface of the large diameter cylindrical portion 137.

The connecting portion 141 has a standing portion 145 erected in parallel with the large-diameter cylindrical portion 137 from a portion corresponding to the space between the concave portions 143 of the large-diameter cylindrical portion 137. The interval between the standing portion 145 and the large diameter cylindrical portion 137 corresponds to the thickness of the cylindrical portion 151 of the main cover 123, and the rear end portion of the cylindrical portion 151 is between the standing portion 145 and the large diameter cylindrical portion 137. Is inserted into the groove formed. The mounting means here is constituted by a recess 143 of the large-diameter cylindrical portion 137 and a groove between the large-diameter cylindrical portion 137 and the standing portion 145.
The small-diameter cylindrical portion 139 has a convex portion 147 that protrudes inward from a portion spaced in the circumferential direction of the inner peripheral surface. The convex portion 147 engages with the locking member 55 of the three cover mounting portions 15 of the apparatus main body. The small-diameter cylindrical portion 139 has a reinforcing vertical rib 148 on the back side of the convex portion 147. The attached means here is constituted by a convex portion 147 of the small diameter cylindrical portion 139.

(2) Main Cover The main cover 123 will be described mainly with reference to FIGS.
The main cover 123 has a cylindrical portion 151 that fits inside the large-diameter cylindrical portion 137 of the mounting cover 121, and a dome portion (partial spherical portion) 153 that projects forward from the front end of the cylindrical portion 151.
The main cover 123 has a first light diffusion region 155 at the center of the dome 153 and a second light diffusion outside the first light diffusion region 155 when the main cover 123 is viewed in the light emission direction. Each of the regions 157 has a third light diffusion region 159 outside the second light diffusion region 157.

When the main cover 123 is viewed from the light emitting direction, the first light diffusion region 155 has a circular shape, and the second and third light diffusion regions 157 and 159 have an annular shape. That is, when the main cover 123 is viewed from the light emitting direction, the second light diffusion region 157 is provided continuously in the circumferential direction on the outer peripheral portion of the first light diffusion region 155. The third light diffusion region 159 is an outer peripheral portion of the second light diffusion region 157 and is provided continuously in the circumferential direction.
The first light diffusion region 155 and the third light diffusion region 159 are subjected to the same material and the same light diffusion treatment. For this reason, the first light diffusion region 155 and the third light diffusion region 159 have the same light diffusibility and light transmittance.

Specifically, the first light diffusion region 155 and the third light diffusion region 159 are formed of a translucent resin material (for example, a thermoplastic resin such as polypropylene), and at least one of the inner surface and the outer surface is formed. It is a light diffusion processed surface. The light diffusion processed surface is, for example, a textured surface, and is a surface formed when injection molding is performed using a textured mold material. Even if the main surface is not directly subjected to light diffusion processing (texture processing), it is referred to as a light diffusion processing surface.
In the first light diffusion region 155 and the third light diffusion region 159, a diffusing agent (for example, a silicone agent) is mixed in the light-transmitting resin material. Thereby, the first light diffusion region 155 and the third light diffusion region 159 appear milky white.

The second light diffusion region 157 is a region having optical characteristics different from those of the first and third light diffusion regions 155 and 159. Specifically, the second light diffusion region 157 is a transparent and transparent resin material (for example, a thermoplastic resin such as acrylic or polycarbonate). And has a light diffusion processing surface different from the light diffusion processing surfaces of the first and third light diffusion regions 155 and 159. In addition, even if the main surface here is not directly light-diffused, the light-diffused surface is also indirectly processed.
At least one surface (herein, the inner surface) of the main surface in the second light diffusion region 157 is a diamond cut surface. That is, the inner surface of the second light diffusion region 157 has a diamond cut pattern 156. As a result, the second light diffusion region 157 has higher light transmission and lower light diffusion than the first and third light diffusion regions 155 and 159.

The diamond cut pattern 156 includes a prism shape having regularity in the circumferential direction of the annular second light diffusion region 157. As an example of the prism shape, more specifically, it has an irregular shape having regularity. In the plan view, the prism shape is the apex 156b (hatched upward to the right in FIG. 14) in which the inside of the plurality of quadrangles 156a arranged in the circumferential direction of the second light diffusion region 157 exists on one side of the two sides extending in the circumferential direction. Is divided into five triangles 156c, 156d, 156e, 156f, and 156g having apex angles, and triangles adjacent in the circumferential direction are ascending and descending along the circumferential direction. The shape is repeated alternately.
The triangle 156c has one side extending in the circumferential direction as a base. The triangles 156d and 156e have two sides extending in the radial direction of the quadrangle 156a as the bases. Triangles 156f and 156g are obtained by dividing a triangle having the other side extending in the circumferential direction of the quadrangle 156a as a base.

The triangles 156e and 156d are adjacent in the circumferential direction, and the triangles 156f and 156g are adjacent in the circumferential direction. In other words, the triangles adjacent in the circumferential direction are two triangles sharing a side extending in the radial direction.
Here, the quadrangle 156a has a substantially rectangular shape with a long side in the radial direction. The diamond cut pattern 156 has a plurality of square shapes arranged in the circumferential direction in the radial direction. The number of steps here is two, and the pattern of each step is axisymmetric with respect to a virtual line located between the two steps and extending in the circumferential direction.

The main cover 123 includes an outer main cover body 163 having an opening 161 on the top side of the dome portion 153, an inner main cover body 165 disposed at the center of the opening 161 of the outer main cover body 163, and an outer main cover body 163. And an intermediate main cover body 167 interposed between the inner main cover body 165. The main cover 123 further includes an auxiliary cover body 169 that assists the connection of the outer main cover body 163, the intermediate main cover body 167, and the inner main cover body 165.
The outer main cover body 163 has a cylindrical portion 151 and a truncated dome portion 173. The cylindrical portion 151 has a convex portion 175 that engages with the concave portion 143 of the large-diameter cylindrical portion 137 of the mounting cover 121 at a circumferentially spaced portion on the outer peripheral surface.
The pier dome part 173 constitutes a third light diffusion region 159. The inner peripheral edge 177 of the wharf dome 173 is a thick part. The pier dome part 173 has a notch 179 at a part of the inner peripheral edge part 177 spaced in the circumferential direction.

The inner main cover body 165 constitutes a first light diffusion region 155. The outer peripheral edge 181 of the inner main cover body 165 is a thick portion. The inner main cover body 165 has a notch 183 at a circumferentially spaced portion in the outer peripheral edge 181.
The intermediate main cover body 167 constitutes a second light diffusion region 157. The intermediate main cover body 167 has an outer pin 187 extending rearward from a circumferentially spaced portion on the outer peripheral edge, and an inner side extending rearward from the circumferentially spaced portion on the inner peripheral edge. A pin 189 is provided. The outer pin 187 is fitted in the notch 179 of the outer main cover body 163. The inner pin 189 fits into the notch 183 of the inner main cover body 165.
The auxiliary cover body 169 has an annular shape (for example, an annular shape). The auxiliary cover body 169 is made of a transparent resin material having translucency, like the intermediate main cover body 167. The outer peripheral edge 190 and the inner peripheral edge 192 of the auxiliary cover body 169 are thick portions. The auxiliary cover body 169 has outer through holes 191 for the outer pins 187 of the intermediate main cover body 167 at the circumferentially spaced portions of the outer peripheral edge 190. The auxiliary cover body 169 has an inner through-hole 193 for the inner pin 189 of the intermediate main cover body 167 at a circumferentially spaced portion in the inner peripheral edge 192.

  The outer pin 187 of the intermediate main cover body 167 passes through the notch 179 of the outer main cover body 163 and the outer through-hole 191 of the auxiliary cover body 169 from the front side, and then the tip portion thereof is hot-collapsed. The inner pin 189 of the intermediate main cover body 167 passes through the notch 183 of the inner main cover body 165 and the inner through-hole 193 of the auxiliary cover body 169 from the front side, and then the tip portion thereof is hot-collapsed. As a result, the outer main cover body 163, the intermediate main cover body 167, the inner main cover body 165, and the auxiliary cover body 169 are integrated to form the main cover 123.

<Second Embodiment>
Although the translucent cover 5 of 1st Embodiment had the attachment cover 121 which has the decoration part 129 in the outermost periphery when it sees from the front side, there may not be the outermost periphery decoration part. 2nd Embodiment demonstrates the illuminating device (ceiling light) provided with the translucent cover which does not have a decoration part.

Hereinafter, the translucent cover will be mainly described, and the details of the other parts are the same as those in the first embodiment, and thus the description thereof will be omitted.
As shown in FIGS. 15 and 16, the ceiling light 201 includes the apparatus main body 3 and a translucent cover 203. As described above, the apparatus main body 3 has the same configuration as the apparatus main body 3 of the first embodiment, and the same reference numerals as those of the respective sections in the first embodiment are used for the description of each part.
As shown in FIG. 16, the apparatus main body 3 includes a light source unit 11, a circuit unit 12, a mounting unit 13, a mounting unit 14, a cover mounting unit 15 (see FIG. 4), a light source cover unit 17, a circuit housing unit 18, and a receiving unit. 19 The translucent cover 203 has a mounting cover 205 and a main cover 123 as shown in FIG. Since the main cover 123 is the same as that of the first embodiment, description thereof is omitted.

The attachment cover 205 will be described mainly with reference to FIGS. 17 and 18.
The mounting cover 205 may be made of a translucent resin material mixed with a diffusing agent, or may be made of a transparent translucent resin. Here, a diffusing agent is mixed in the same translucent resin material (polypropylene) as the inner main cover body 165 of the main cover 123, and has a light diffusion processed surface.
The attachment cover 205 has a stepped cylindrical shape that expands on the front side. The attachment cover 205 has the same configuration as the auxiliary portion 127 of the attachment cover 121 of the first embodiment.

The attachment cover 205 has a large diameter cylindrical portion 211, a connecting portion 213, and a small diameter cylindrical portion 215. The large-diameter cylindrical portion 211 has a concave portion 217 that is recessed at a circumferentially spaced portion on the inner peripheral surface and engages with the convex portion 175 of the cylindrical portion 151 in the main cover 123. The connecting portion 213 has a standing portion 219 that stands in parallel with the large-diameter cylindrical portion 211 from a portion corresponding to the space between the concave portions 217 of the large-diameter cylindrical portion 211. The rear end portion of the cylindrical portion 151 of the main cover 123 is inserted between the standing portion 219 and the large-diameter cylindrical portion 211.
The small-diameter cylindrical portion 215 has a convex portion 221 that protrudes inward from a portion spaced in the circumferential direction of the inner peripheral surface and engages with the locking tool 55 of the cover mounting portion 15 of the apparatus main body 3. The small-diameter cylindrical portion 215 has a reinforcing vertical rib 223 on the back side of the convex portion 221.

<Light diffusion region>
1. First Light Diffusion Region and Third Light Diffusion Region The first and third light diffusion regions 155 and 159 of the translucent cover 5 in the embodiment have a function of diffusing light emitted from the LED 21 and have directivity. The glare is prevented when the strong LED 21 is used as a light source. The light diffusing function in the first and third light diffusing regions 155 and 159 can be achieved, for example, by mixing a diffusing agent into the translucent resin material, or by applying a texture to the back and front surfaces of the outer main cover body 163 and the inner main cover body 165. It is carried out by making it into a processed surface. However, as the light diffusion processing of the first and third light diffusion regions 155, 159, for example, blast processing, light diffusion film formation processing, or the like can be used in addition to the texture processing.

  In addition, although the 1st light diffusion area | region 155 and the 3rd light diffusion area | region 159 in embodiment were the same material and the same light-diffusion process (light-diffusion process), even if each uses another material and light-diffusion process. Good. However, the first light diffusion region and the third light diffusion region need to have light diffusibility different from that of the second light diffusion region. Specifically, the third light diffusion region needs to have lower light transmission than the second light diffusion region, and higher light diffusion than the second light diffusion region. Thereby, the difference between the luminous intensity of the light emitted from the first light diffusion area and the third light diffusion area and the luminous intensity of the light emitted from the second light diffusion area is increased, and the glittering feeling of the second light diffusion area is increased. Can be improved.

2. Second Light Diffusion Region (1) Diamond Cut Pattern The second light diffusion region 157 is made of a transparent translucent resin material and has a diamond cut pattern on the back surface. The diamond cut pattern can be obtained by injection molding using a die that has been diamond cut. However, you may make it a 2nd light-diffusion area | region have a diamond-cut pattern by a diamond-cut process using a glass material, for example.
As the diamond cut pattern, for example, a quadrangular shape having a long side in the circumferential direction of the annular second light diffusion region may be used, or a square shape having substantially the same length in the circumferential direction and the radial direction may be used. May be. In addition, the quadrangular shape is provided in a straight line in the circumferential direction. However, for example, the quadrangular shape may be provided in a zigzag shape in the circumferential direction as a rhombus. Further, an n-corner shape (“n” is an even number of 4 or more) can be used instead of a quadrangle. Furthermore, a plurality of types of polygonal shapes may be used. For example, it may be a pattern in which octagons are densely arranged and quadrangles are arranged in empty portions.

The size of one square is preferably in the range of 40 [mm ² ] or more and 50 [mm ² ] or less, more preferably in the range of 44 [mm ² ] or more and 46 [mm ² ] or less. By making it in this range, it is possible to improve the feeling of glitter of the light emitted from the second light diffusion region.
Further, when a substantially rectangular shape is used for the diamond-cut pattern, the ratio of the short side to the long side (short side / long side) is preferably in the range of 0.5 to 0.8, and 0.6 to 0.7. The following ranges are more preferable. Thereby, the feeling of glitter of the light emitted from the second light diffusion region can be improved.
Moreover, when using the triangular uneven | corrugated surface which contains the top 156b in a diamond-cut pattern, the unevenness | corrugation (top height) has the preferable range of 1.0 [mm] or more and 2.0 [mm] or less, and 1.4 A range of [mm] to 1.6 [mm] is more preferable. Thereby, the feeling of glitter of the light emitted from the second light diffusion region can be improved.
Although the number of squares in the radial direction is two in the embodiment, it may be one or more than three. When there are a plurality of stages, the same pattern may be used in each stage, or different patterns may be used. The number of steps is appropriately determined depending on the size of the glitter area and the size of the pattern (for example, the size of a square).

(2) Number and shape of second light diffusion regions The second light diffusion regions 157 of the embodiment are annular. The number may be one or two or more. The outer peripheral edge and the inner peripheral edge of the second light diffusion region 157 have a circular shape, but may have a polygonal shape such as a rectangular shape. Further, the shape may be different between the outer peripheral edge and the inner peripheral edge of the second light diffusion region. An example of this is when the outer periphery is circular and the inner periphery is square. Furthermore, although the second light diffusion region has an annular shape with the same radius, it may have a zigzag annular shape that goes back and forth inside the virtual reference circle.
In the embodiment, when the translucent cover 5 is viewed in the light emission direction, the outer peripheral shape of the translucent cover 5 and the ring shape of the second light diffusion region 157 correspond to each other. The shape of the light diffusion region may be different from the outer peripheral shape of the translucent cover. In consideration of design, it is preferable that the second light diffusion region and the outer peripheral shape of the translucent cover correspond to each other.

(3) Occupancy ratio of second light diffusion region In the embodiment, when the translucent cover 5 is viewed in the light emitting direction (when viewed from the floor side when the installation surface is a ceiling), the center side To the first light diffusion region 155, the second light diffusion region 157, and the third light diffusion region 159 in this order. Since the first and third light diffusion regions 155 and 159 have the same light transmission property and light diffusion property, they can be regarded as the same light diffusion region. The ratio of the second light diffusion region 157 to the entire region in this case (total projected area of the second light diffusion region 157 / (total projected area of the first light diffusion region, the second light diffusion region, and the third light diffusion region) ) Is preferably in the range of 15 [%] to 23 [%], more preferably in the range of 17 [%] to 21 [%], while suppressing the glare. A glittering feeling can be obtained.

(4) Width When the ceiling light 1 is viewed from the light emission direction, the inner diameter of the second light diffusion region 157 is D1 and the outer diameter is D2, as shown in FIG. (D2-D1) / 2. The width of the second light diffusion region 157 is in the range of 56 [mm] to 68 [mm], preferably in the range of 61 [mm] to 63 [mm]. Within this range, the balance between the overall luminous intensity and the luminous intensity of the light emitted from the second light diffusion region is improved.

(5) Position in Cross Section The positional relationship between the LED 21 and the second light diffusion region 157 (167) will be described with reference to FIG.
The position of the second light diffusion region 157 is a ½ beam angle (from the LED 21) with respect to the optical axes (X1, X2) of all the LEDs 21 in the cross section of the ceiling light 1 (the cross section in the direction orthogonal to the installation surface). The luminous intensity of the emitted light is in the range of an angle A that is twice the angle between the light emitting direction and the optical axis, which is ½ of the maximum luminous intensity. As a result, light having a high luminous intensity enters the second light diffusion region 157, and the glittering feeling of the second light diffusion region 157 is improved. In addition, when a plurality of types of LEDs 21 having different light colors are used, light emitted from the plurality of types of LEDs 21 directly reaches the second light diffusion region 157, and a glittering feeling with different light colors can be obtained.

In the present embodiment, the second light diffusion region 157 is provided in an annular shape when the ceiling lights 1,201 are viewed in the light emitting direction, and a plurality of sheets are provided when the apparatus body 3 is viewed in the light emitting direction. The mounting substrate 23 is arranged in a ring shape. The second light diffusion region 157 is provided so as to overlap the mounting substrate 23 arranged in an annular shape when viewed in the light emitting direction. As a result, the second light diffusion region 157 is often located within a range of a ½ beam angle (120 ° in this example) A with respect to the optical axis (X1, X2) of the LED 21.
In the present embodiment, the second light diffusion region 157 is located on the optical axis (X1) of the LED 21 closest to the second light diffusion region 157 when the device body 3 is viewed in the light emitting direction. The second light diffusion region 157 is an angle that is twice the angle between the light emitting direction and the optical axis (X1) where the luminous intensity of the light emitted from the LED 21 is 90% of the maximum luminous intensity in the closest LED 21. It suffices to be within the range of B (in this example, 50 °). Thereby, the light with high luminous intensity emitted from the LED 21 is directly incident on the second light diffusion region 157, and the glittering feeling can be improved.

3. The first to third light diffusion regions main cover 123 includes an outer main cover body 163, an inner main cover body 165, and an intermediate main cover body 167 as separate bodies. The first light diffusion region 155 and the second light cover region 167 are provided in each cover body. A light diffusion region 157 and a third light diffusion region 159 are provided.
However, the outer main cover body, the inner main cover body, and the intermediate main cover body may be integrated, and the first to third light diffusion regions may be provided. For example, the main cover is made of a highly light transmissive material, the front and back surfaces of the first light diffusion region and the third light diffusion region are textured surfaces, and at least one surface of the front and back surfaces of the second light diffusion region is diamond cut processed It can be implemented by using a surface.

<Modification>
The lighting devices according to the two embodiments have been described above. However, the present invention is not limited to this embodiment. For example, the following modifications may be used. Moreover, what combined embodiment, the modification, and modifications may be sufficient.
In addition, examples that are not described in the embodiments and modifications and design changes that do not depart from the gist are also included in the present invention.

1. Translucent Cover The translucent cover 5 in the embodiment has a structure in which the mounting cover 121 and the main cover 123 are assembled separately, but the mounting cover and the main cover are integrated from the beginning. It may be a structure. Even in this case, since the main cover includes at least the first light diffusion region and the second light diffusion region, the optical added value can be improved.
The mounting cover 121 of the first embodiment and the second diffusion region 157 (intermediate main cover body 167) of the first and second embodiments are configured to be colorless and transparent. At least one of the regions may be configured to be colored and transparent.
As the color, there are light colors, for example, light blue, light green, light red, and the like. In particular, in the case of a light green color, the optical added value can be further improved when the light color emitted from the light source unit 11 is a daylight color system.
Examples of the coloration method include application of a colored transparent resin material, injection molding with a colored transparent resin material, and pasting of a colored translucent film.

2. Illuminating device The illuminating device should just have the apparatus main body which has the light source part using LED, and a translucent cover. Therefore, the apparatus main body may include the circuit unit 12 on the back side of the mounting unit 13 or the circuit unit on the front side of the mounting unit. Furthermore, the lighting device may have a lighting circuit separately from the device main body. Similarly, the apparatus main body may not include the light source cover part, and the light source cover part may be formed of a plurality of members or a single member.
Moreover, although the illuminating device of embodiment was the ceiling light 1, for example, a pendant type illuminating device may be sufficient, it may be an illuminating device with which a wall is mounted | worn, and it is on installation surfaces, such as a ceiling. The long illuminating device embedded may be sufficient. In this case, what is necessary is just to change suitably the light diffusibility of the 2nd light-diffusion area | region, light transmittance, a position, etc. according to the intended purpose.

1 Ceiling light (lighting device)
DESCRIPTION OF SYMBOLS 3 Device main body 5 Translucent cover 11 Light source part 123 Main cover 155 1st light-diffusion area | region 157 2nd light-diffusion area | region
159 Third light diffusion region

Claims (7)

In an illuminating device comprising a device body having a light source unit and a mounting unit on which the light source unit is mounted, and a translucent cover that covers the light source unit,
The translucent cover is configured by independently combining a plurality of different light diffusion regions,
When the translucent cover is viewed toward the side from which light is emitted from the light source unit, the first light diffusion region is present at the center, and the second light diffusion region is outside the first light diffusion region. A lighting device in the periphery. The lighting device according to claim 1, wherein the second light diffusion region has lower light diffusibility than the first light diffusion region. The illumination device according to claim 1, wherein a main surface of the second light diffusion region has a diamond cut pattern. The illumination device according to claim 3, wherein a main surface of the second light diffusion region is a surface facing the light source unit. The lighting device according to any one of claims 1 to 4, wherein a third light diffusion region exists in an outer peripheral portion of the second light diffusion region. The light diffusion property of the third light diffusion region is the same as the light diffusion property of the first light diffusion region,
The lighting device according to claim 5, wherein the light transmittance of the third light diffusion region is the same as the light transmittance of the first light diffusion region. The illumination according to any one of claims 1 to 6, wherein the second light diffusion region has an annular shape when the translucent cover is viewed toward a side where light is emitted from the light source unit. apparatus.

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