JP2016225116A - Luminaire and container holder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a luminaire capable of reducing unevenness of brightness on the inner peripheral surface of an annular irradiation part, and provide a container holder.SOLUTION: A luminaire includes: an irradiation part formed into an annular shape, and configured to radiate light from an inner peripheral surface; an incident part of which one end is provided on the outer peripheral surface of the irradiation part, and the other end is provided at a position away from the irradiation part; a light-emitting part having a light-emitting element, and provided so as to face the other end of the incident part; and a recess part having a first reflection surface reflecting part of light having been introduced into the incident part, provided near the connection part between the incident part and the irradiation part, and opened to the outer peripheral surface of the irradiation part.SELECTED DRAWING: Figure 3

Description

  Embodiments described herein relate generally to a lighting device and a container holder.

There is an illuminating device including an annular irradiation unit and a light emitting diode for introducing light into the irradiation unit.
According to such an illumination device, it is possible to irradiate light inside the annular irradiation unit.
For example, it is possible to irradiate the member provided inside the annular irradiation portion with light from the surroundings, or to shine the inner peripheral surface of the annular irradiation portion to serve as a mark when the member is provided.
However, such an illumination device has a problem that uneven brightness occurs on the inner peripheral surface of the annular irradiation section.

JP 2001-118463 A

  The problem to be solved by the present invention is to provide an illuminating device and a container holder that can reduce unevenness in brightness on the inner peripheral surface of an annular irradiation section.

  The illumination device according to the embodiment has an annular shape and an irradiation unit that emits light from an inner peripheral surface; one end is provided on the outer peripheral surface of the irradiation unit, and the other end is provided at a position separated from the irradiation unit An incident portion; a light emitting portion that includes a light emitting element and is provided opposite to the other end of the incident portion; and a first reflecting surface that reflects a part of the light introduced into the incident portion, A concave portion provided in the vicinity of a connection portion between the incident portion and the irradiation portion and opening on an outer peripheral surface of the irradiation portion.

  According to the embodiment of the present invention, it is possible to provide an illuminating device and a container holder that can reduce unevenness in brightness on the inner peripheral surface of the annular irradiation section.

It is a model perspective view for illustrating container holder 100 concerning this embodiment. It is a typical exploded view for illustrating container holder 100 concerning this embodiment. It is a schematic diagram for illustrating the illuminating device 1 which concerns on this Embodiment. 3 is a schematic partial perspective view for illustrating a cross-sectional shape of an illumination unit 3. FIG. It is a schematic diagram for illustrating the illumination part 30 which concerns on a comparative example. It is a schematic diagram for illustrating the recessed part 3h (3i). It is a schematic diagram for illustrating the illumination part 13 which concerns on other embodiment. It is a schematic diagram for illustrating hole 13a (13b). It is a schematic diagram for illustrating the illumination part 23 which concerns on other embodiment. It is a schematic diagram for illustrating the illumination part 33 which concerns on other embodiment. It is a model perspective view for illustrating the container holder 110 which can hold | maintain one container. 4 is a schematic diagram for illustrating an irradiation unit 43 provided in the container holder 110. FIG. It is a schematic perspective view for illustrating the arrangement | positioning form of the incident part which concerns on other embodiment.

The illumination device according to the embodiment has an annular shape and an irradiation unit that emits light from an inner peripheral surface; one end is provided on the outer peripheral surface of the irradiation unit, and the other end is provided at a position separated from the irradiation unit An incident portion; a light emitting portion that includes a light emitting element and is provided opposite to the other end of the incident portion; and a first reflecting surface that reflects a part of the light introduced into the incident portion, A concave portion provided in the vicinity of a connection portion between the incident portion and the irradiation portion and opening on an outer peripheral surface of the irradiation portion.
According to this illumination device, it is possible to reduce uneven brightness on the inner peripheral surface of the annular irradiation unit.

In this case, the light introduced into the incident part and not incident on the first reflecting surface propagates in the first direction inside the irradiation part.
The concave portion reflects light incident on the first reflecting surface by the first reflecting surface, and propagates the inside of the irradiation unit in a second direction different from the first direction.
In this way, the light introduced into the incident portion can be distributed at an appropriate ratio.

  Further, the first reflecting surface can totally reflect the incident light. In this way, the utilization efficiency of light incident on the first reflecting surface can be improved.

The illumination device further includes a hole portion provided in the vicinity of a connection portion between the incident portion and the irradiation portion and having a second reflection surface that reflects light reflected by the first reflection surface. Can do.
In this way, it is possible to reduce the amount of light that is directly incident on the inner peripheral surface of the irradiation section. Therefore, the uneven brightness on the inner peripheral surface of the irradiation unit can be further reduced.

The second reflecting surface may totally reflect incident light.
In this way, the utilization efficiency of light incident on the second reflecting surface can be improved.

In addition, the container holder according to the embodiment includes a cover portion having a hole portion for inserting a container; an opening for inserting the container, and a holding portion provided so that the opening portion faces the hole portion of the cover portion. A lighting unit provided between the cover unit and the holding unit.
According to this container holder, unevenness in brightness on the inner peripheral surface of the annular irradiation unit can be reduced, so that it is possible to reduce a sense of discomfort when viewing the inner peripheral surface of the irradiation unit.
Therefore, merchantability can be improved.

Hereinafter, embodiments will be illustrated with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.
FIG. 1 is a schematic perspective view for illustrating a container holder 100 according to the present embodiment.
FIG. 2 is a schematic exploded view for illustrating the container holder 100 according to the present embodiment.
FIG. 3 is a schematic diagram for illustrating the lighting device 1 according to the present embodiment.
FIG. 4 is a schematic partial perspective view for illustrating the cross-sectional shape of the illumination unit 3.

As shown in FIGS. 1 and 2, the container holder 100 is provided with a cover portion 101, a holding portion 102, and the lighting device 1.
The container holder 100 illustrated in FIGS. 1 and 2 can hold up to two containers.
The container to be held by the container holder 100 can be, for example, a container in which a beverage is stored. The container can be, for example, a cup, can, bottle, or the like made of paper or resin.

  The container holder 100 can be provided in a room of a moving body such as an automobile, a railway vehicle, an aircraft, or a ship. In this case, the container holder 100 can be provided in the vicinity of a seat on which an occupant sits, for example.

Further, when the container is held by the container holder 100, the end portion of the container protrudes from the cover portion 101.
And in the state which has not inserted the container, the inner peripheral surface 3g (light emission surface) of the illumination part 3 can be visually observed through the hole 101a of the cover part 101. FIG.

The cover 101 has a plate shape and is provided with a hole 101a for inserting a container.
The hole portion 101a penetrates the cover portion 101 in the thickness direction. The size and shape of the hole 101a are the same as the size and shape of the hole inside the illumination unit 3. Therefore, when the container holder 100 is assembled, the edge of the hole 101a and the inner peripheral surface of the illumination unit 3 overlap in plan view.
The material of the cover part 101 is not particularly limited. For example, if the resin part is used, the cover part 101 can be easily manufactured.
Moreover, the cover part 101 may have light-shielding property and may have translucency.

Bonding of the cover unit 101 and the lighting device 1 can be, for example, bonding with an adhesive.
However, joining of the cover part 101 and the illuminating device 1 is not necessarily required, for example, the illuminating device 1 may be only sandwiched between the cover part 101 and the holding part 102.
Moreover, the cover part 101 can also be used as a vehicle interior material.

The holding part 102 has a box shape, and one end side is open. The other end side of the holding part 102 may be opened or may not be opened. The holding portion 102 is provided with an opening facing the hole portion 101 a of the cover portion 101.
A container is inserted into the opening of the holding unit 102, and the inserted container can be held by at least one of the inner side wall and the inner bottom surface of the holding unit 102.

The holding | maintenance part 102 has a shape where a cross-sectional area reduces gradually as it goes to the opposite side to the side in which the illuminating device 1 is provided.
The material of the holding unit 102 is not particularly limited. For example, if the resin is used, the manufacturing of the holding unit 102 is facilitated.
In addition, when the light emitting element 2b generates a large amount of heat, the holding portion 102 can be formed using a material having high thermal conductivity.

The material having high thermal conductivity can be, for example, high thermal conductive resin, metal, ceramics such as aluminum oxide and aluminum nitride.
The high thermal conductive resin is, for example, a resin such as PET (Polyethyleneterephthalate) or nylon mixed with fibers or particles made of carbon or aluminum oxide having high thermal conductivity.

A mounting seat 102 a that protrudes outward from the holding portion 102 is provided at the opening end of the holding portion 102.
The housing part 2a of the light emitting part 2 is attached to the attachment seat 102a. For example, the housing 2a of the light emitting unit 2 is screwed to the mounting seat 102a.

The holding unit 102 and the lighting device 1 can be bonded by, for example, bonding with an adhesive.
However, the joining of the holding unit 102 and the lighting device 1 is not necessarily required. For example, the lighting device 1 may be simply sandwiched between the cover unit 101 and the holding unit 102.
Moreover, the holding | maintenance part 102 can also be used as the member etc. which are provided in a vehicle, for example.

The lighting device 1 is provided between the cover unit 101 and the holding unit 102.
As shown in FIG. 3, the lighting device 1 includes a light emitting unit 2 and a lighting unit 3.

The light emitting unit 2 is provided with a housing 2a and a light emitting element 2b.
In the case of the example illustrated in FIG. 3, two light emitting units 2 are provided.

  The light emitted from the light emitting unit 2 is introduced into the illumination unit 3 (incident units 3b and 3d) and propagates through the illumination unit 3. At this time, since the propagating light is attenuated, there is a possibility that the intensity of the light irradiated from the illumination unit 3 becomes weaker as the propagating distance becomes longer. In this case, if a plurality of light emitting units 2 are provided, the propagation distance of one light emitting unit 2 can be shortened, so that the intensity of light emitted from the illumination unit 3 can be easily increased. On the other hand, when the number of the light emitting units 2 is increased, the lighting device 1 is increased in size and cost.

Therefore, the number of the light emitting units 2 can be changed as appropriate so that the intensity of light emitted from the illuminating unit 3 becomes a predetermined value or more.
In addition, if the intensity | strength of the light irradiated from the illumination part 3 is more than predetermined value, the number of the light emission parts 2 may be one.

The housing portion 2a holds the light emitting element 2b and protects the light emitting element 2b.
The casing 2a has a T-shaped planar shape, and one end is a light irradiation surface 2a1. An optical element such as a lens can be provided on the irradiation surface 2a1.

A mounting portion 2a2 is provided at the other end of the housing portion 2a.
When assembling the container holder 100, the mounting portion 2a2 is placed on the mounting seat 102a of the holding portion 102, and, for example, a tapping screw is screwed into the hole provided in the mounting portion 2a2, thereby the housing 102 is mounted on the holding portion 102. The part 2a and by extension the light emitting part 2 can be attached.

The material of the housing part 2a is not particularly limited. For example, if the resin is used, the housing part 2a can be easily manufactured.
Moreover, when the emitted-heat amount of the light emitting element 2b is large, the housing | casing part 2a can also be formed using a material with high heat conductivity.
The material having high thermal conductivity can be, for example, the above-described high thermal conductive resin, metal, ceramic such as aluminum oxide or aluminum nitride.

The light emitting element 2b is provided inside the housing portion 2a and emits light toward the irradiation surface 2a1.
The light emitting element 2b can be, for example, a light emitting diode or a laser diode.
There is no particular limitation on the number of the light emitting elements 2b. The number of the light emitting elements 2b can be appropriately changed according to the size of the illumination unit 3 (incident units 3b and 3d). That is, the number of the light emitting elements 2b may be one or more.

There is no limitation in particular in the form of the light emitting element 2b. The light emitting element 2b may be, for example, a cannonball type light emitting element or a surface mount type (chip type) light emitting element.
Terminals (not shown) provided on the light emitting element 2b are exposed from the housing 2a. An external power source or the like is connected to a terminal (not shown) exposed from the housing 2a via a connector or the like.

The color of the light emitted from the light emitting unit 2 is not particularly limited. The color of light emitted from the light emitting unit 2 can be appropriately changed in consideration of, for example, the color and design of the interior material of the vehicle.
The color of the light emitted from the light emitting unit 2 can be changed by, for example, providing a wavelength conversion unit made of a resin containing a phosphor and appropriately selecting the type of the phosphor.
For example, when the light emitting element 2b is a blue light emitting diode and the phosphor is a YAG phosphor (yttrium, aluminum, garnet phosphor), the YAG phosphor is excited by blue light emitted from the blue light emitting diode. Then, yellow fluorescence is emitted from the YAG phosphor. Then, white light is emitted from the light emitting unit 2 by mixing the blue light and the yellow light.
As described above, the color of the light emitted from the light emitting unit 2 can be changed by appropriately selecting the type of the phosphor.

The illumination unit 3 includes a first irradiation unit 3a, an incident unit 3b, a second irradiation unit 3c, an incident unit 3d, a third irradiation unit 3e, a fourth irradiation unit 3f, a recess 3h, and a recess 3i.
The first irradiation unit 3a, the incident unit 3b, the second irradiation unit 3c, the incident unit 3d, the third irradiation unit 3e, and the fourth irradiation unit 3f are made of, for example, a transparent resin such as an acrylic resin or a polycarbonate resin. Can be formed.
The 1st irradiation part 3a, the 2nd irradiation part 3c, the 3rd irradiation part 3e, and the 4th irradiation part 3f are integrally formed, and become an irradiation part which exhibits a ring shape in planar view.
The inner peripheral surface 3g (the inner peripheral surface 3g of the illumination unit 3) of the irradiation unit including the first irradiation unit 3a, the second irradiation unit 3c, the third irradiation unit 3e, and the fourth irradiation unit 3f is light. It is a surface (light emitting surface) to irradiate. That is, the annular irradiation unit irradiates light from the inner peripheral surface 3g.

The shape of the inner peripheral surface 3a1 of the first irradiation part 3a can be made similar to a part of the shape of the outer peripheral surface of the container to be inserted.
In the case illustrated in FIG. 3, the shape of the inner peripheral surface 3 a 1 of the first irradiation unit 3 a in a plan view is a part of a circle.

The incident portion 3b has a rod shape and projects outward from the first irradiation portion 3a.
One end of the incident part 3b is connected to the outer peripheral surface of the first irradiation part 3a. The other end of the incident part 3b is provided at a position separated from the first irradiation part 3a. The other end of the incident part 3 b faces the light emitting part 2. The other end of the incident portion 3b is an incident surface on which light from the light emitting portion 2 is incident.

  The 2nd irradiation part 3c shall have a shape and a dimension similar to the 1st irradiation part 3a. In this case, the second irradiation unit 3c can be point-symmetric with the first irradiation unit 3a with respect to the center of the illumination unit 3.

The incident part 3d can have the same shape and dimensions as the incident part 3b. In this case, the incident part 3d can be made point-symmetric with the incident part 3b with respect to the center of the illumination part 3.
In the case of the example illustrated in FIG. 3, since the two light emitting units 2 are provided, the incident unit 3 b and the incident unit 3 d are provided. However, in the case of one light emitting unit 2, the incident unit 3 b or The incident part 3d should just be provided.
The number of incident portions can be the same as the number of light emitting portions 2.

The third irradiation unit 3e is provided between the first irradiation unit 3a and the second irradiation unit 3c.
One end of the third irradiation unit 3e is provided at one end of the first irradiation unit 3a, and the other end of the third irradiation unit 3e is provided at one end of the second irradiation unit 3c.

  The fourth irradiation unit 3f is provided between the first irradiation unit 3a and the second irradiation unit 3c. One end of the fourth irradiation unit 3f is provided at the other end of the first irradiation unit 3a, and the other end of the fourth irradiation unit 3f is provided at the other end of the second irradiation unit 3c.

There are no particular limitations on the cross-sectional shapes of the first irradiation unit 3a, the incident unit 3b, the second irradiation unit 3c, the incident unit 3d, the third irradiation unit 3e, and the fourth irradiation unit 3f.
However, as shown in FIG. 4, if these cross-sectional shapes are rectangular, the adhesion between the illumination unit 3 and the cover unit 101 and the adhesion between the illumination unit 3 and the holding unit 102 are improved. Can be made.

Surfaces other than the inner peripheral surface 3g of the illumination unit 3 cannot be visually recognized from the outside. On the other hand, the inner peripheral surface 3 g of the illumination unit 3 can be viewed from the outside through the hole 101 a of the cover unit 101.
In this case, if there is uneven brightness on the inner peripheral surface 3g, a passenger may feel uncomfortable when viewing the inner peripheral surface 3g of the illumination unit 3. Therefore, the commercial value of the illuminating device 1 and by extension, the container holder 100 may fall.

FIG. 5 is a schematic diagram for illustrating the illumination unit 30 according to the comparative example.
As shown in FIG. 5, the light L introduced into the irradiation unit 30a through the incident unit 30b is introduced into the irradiation unit 30c through the irradiation unit 30e.
Since the light is attenuated as the propagation distance becomes longer, the intensity of the light L introduced to the side of the irradiation unit 30c to which the irradiation unit 30f is connected becomes weaker.
In addition, since the light is highly linear, the light L ′ introduced from the incident part 30d is difficult to be introduced to the side of the irradiation part 30c to which the irradiation part 30e is connected.
Therefore, the A part in FIG. 5 becomes dark.

Further, the light L ′ introduced into the irradiation unit 30 c through the incident unit 30 d is introduced into the irradiation unit 30 a through the irradiation unit 30 f.
Since the light is attenuated as the propagation distance becomes longer, the intensity of the light L ′ introduced to the side of the irradiation unit 30a to which the irradiation unit 30e is connected becomes weaker.
In addition, since the light is highly linear, the light L introduced from the incident part 30b is not easily introduced to the side of the irradiation part 30a to which the irradiation part 30f is connected.
Therefore, the B part in FIG. 5 becomes dark.
That is, uneven brightness occurs on the inner peripheral surface 30g.

Therefore, in the illumination unit 3 according to the present embodiment, a recess 3h is provided in the vicinity of the connection portion between the incident unit 3b and the first irradiation unit 3a. The recess 3h is open to the outer peripheral surface of the first irradiation unit 3a. The recess 3h has a reflecting surface 3h1 (corresponding to an example of a first reflecting surface) that reflects a part of the light introduced into the incident portion 3b.
Moreover, the recessed part 3i is provided in the vicinity of the connection part of the incident part 3d and the 2nd irradiation part 3c. The recessed part 3i is opened in the outer peripheral surface of the 2nd irradiation part 3c. The recess 3i has a reflection surface 3i1 (corresponding to an example of a first reflection surface) that reflects part of the light introduced into the incident portion 3d.

FIG. 6 is a schematic diagram for illustrating the recess 3h (3i).
As shown in FIG. 6, the recess 3 h is open to the outer peripheral surface of the first irradiation unit 3 a. Therefore, the recess 3h is filled with gas (generally air) contained in the environment in which the illumination unit 3 is provided. The reflecting surface 3h1 reflects light according to the difference between the refractive index of the material of the illumination unit 3 and the refractive index of the gas.
The reflecting surface 3h1 of the recess 3h faces the incident surface 3b1 of the incident portion 3b. The area of the reflecting surface 3h1 is smaller than the area of the incident surface 3b1.
An angle θ formed by the side surface 3b2 of the incident portion 3b and the reflecting surface 3h1 is larger than 90 °.
It is preferable that the angle θ be an angle at which the incident light L1 can be totally reflected.
If the reflection surface 3h1 totally reflects the incident light L1, the utilization efficiency of the light L1 incident on the reflection surface 3h1 can be improved.

Part of the light (light L1) introduced from the incident surface 3b1 into the incident portion 3b is incident on the reflecting surface 3h1, reflected by the reflecting surface 3h1, and the fourth irradiating portion 3f of the first irradiating portion 3a. Introduced on the connected side. The light L2 that has not entered the reflecting surface 3h1 is introduced to the side of the first irradiation unit 3a to which the third irradiation unit 3e is connected. That is, the light L2 that is introduced into the incident portion 3b and does not enter the reflecting surface 3h1 propagates in a predetermined direction (corresponding to an example of the first direction) inside the irradiation portion. The recess 3h reflects the incident light L1 on the reflecting surface 3h1, and propagates the inside of the irradiation unit in a direction (corresponding to an example of the second direction) different from the direction in which the light L2 propagates.
In this way, the concave portion 3h allows the light introduced into the incident portion 3b to be transmitted to the side of the first irradiation portion 3a to which the fourth irradiation portion 3f is connected and the third irradiation portion 3a. Distribute to the side to which the irradiation unit 3e is connected.
In this case, the light distribution ratio can be changed as appropriate so that the unevenness in brightness on the inner peripheral surface 3g of the illumination unit 3 is reduced.
The light distribution ratio can be appropriately set by changing the area of the reflecting surface 3h1, the arrangement position of the reflecting surface 3h1, and the angle θ.

The recessed part 3i is opened in the outer peripheral surface of the 2nd irradiation part 3c. For this reason, the recess 3i is filled with gas (generally air) contained in the environment in which the illumination unit 3 is provided. The reflecting surface 3i1 reflects light according to the difference between the refractive index of the material of the illumination unit 3 and the refractive index of the gas.
The reflecting surface 3i1 of the recess 3i is opposed to the incident surface 3d1 of the incident portion 3d. The area of the reflecting surface 3i1 is smaller than the area of the incident surface 3d1.
An angle θ formed by the side surface 3d2 of the incident portion 3d and the reflecting surface 3i1 is larger than 90 °.
It is preferable that the angle θ be an angle at which the incident light L1 can be totally reflected.
If the reflection surface 3i1 totally reflects the incident light L1, the utilization efficiency of the light L1 incident on the reflection surface 3i1 can be improved.

A part of the light (light L1) introduced from the incident surface 3d1 into the incident portion 3d is incident on the reflecting surface 3i1, reflected by the reflecting surface 3i1, and the third irradiating portion 3e of the second irradiating portion 3c. Introduced on the connected side. The light L2 that has not entered the reflecting surface 3i1 is introduced to the side of the second irradiation unit 3c to which the fourth irradiation unit 3f is connected. That is, the light L2 introduced into the incident portion 3d and not incident on the reflecting surface 3i1 propagates in the predetermined direction (corresponding to an example of the first direction) inside the irradiation portion. The concave portion 3i reflects the incident light L1 on the reflecting surface 3i1, and propagates the inside of the irradiation unit in a direction (corresponding to an example of the second direction) different from the direction in which the light L2 propagates.
In this way, the concave portion 3i allows the light introduced into the incident portion 3d to pass through the side of the second irradiation portion 3c to which the third irradiation portion 3e is connected and the fourth irradiation portion 3c. Distribute to the side to which the irradiation unit 3f is connected.
In this case, the light distribution ratio can be changed as appropriate so that the unevenness in brightness on the inner peripheral surface 3g of the illumination unit 3 is reduced.
The light distribution ratio can be changed as appropriate by changing the area of the reflecting surface 3i1, the position where the reflecting surface 3i1 is disposed, and the angle θ.
Moreover, although the recessed parts 3h and 3i which exhibit a triangular shape in planar view were illustrated, if it has the reflective surfaces 3h1 and 3i1, there will be no limitation in particular in the shape of the recessed parts 3h and 3i.

FIG. 7 is a schematic diagram for illustrating an illumination unit 13 according to another embodiment.
FIG. 8 is a schematic diagram for illustrating the hole 13a (13b).
As shown in FIG. 7, the illumination unit 13 includes a first irradiation unit 3a, an incident unit 3b, a second irradiation unit 3c, an incident unit 3d, a third irradiation unit 3e, a fourth irradiation unit 3f, and a recess 3h. , A recess 3i, a hole 13a, and a hole 13b.
That is, the illumination unit 13 is obtained by further providing a hole 13 a and a hole 13 b in the illumination unit 3.

If the amount of light reflected by the reflecting surface 3h1 (3i1) and directly incident on the inner peripheral surface 3g of the illuminating unit 13 is large, the region where the light is directly incident may become too bright.
For this reason, the illumination unit 13 is provided with a hole 13a (13b) so that the amount of light directly incident on the inner peripheral surface 3g of the illumination unit 13 does not become excessive.

  As shown in FIG. 8, the hole 13a is provided in the vicinity of the connection portion between the incident portion 3b and the first irradiation portion 3a. The hole 13a does not open on the side surface 3b2 side of the incident portion 3b and the inner peripheral surface 3g of the illumination portion 13 (outside and inside of the illumination portion 13 in plan view). The hole 13a penetrates the illumination unit 13 (first irradiation unit 3a) in the thickness direction. Therefore, the inside of the hole 13a is filled with gas (generally air) contained in the environment where the illumination unit 13 is provided. The hole 13a has a reflective surface 13a1. The reflecting surface 13a1 reflects light according to the difference between the refractive index of the material of the illumination unit 3 and the refractive index of the gas. The reflection surface 13a1 is provided at a position where the light L1 reflected by the reflection surface 3h1 enters. The angle formed by the reflecting surface 13a1 and the light L1 reflected by the reflecting surface 3h1 is preferably an angle that allows the incident light L1 to be totally reflected. If the reflection surface 13a1 totally reflects the incident light L1, the utilization efficiency of the light incident on the reflection surface 13a1 can be improved.

  The light L1 incident on the reflecting surface 13a1 is reflected by the reflecting surface 13a1 and the propagation direction is changed. At this time, the propagation direction of the light L1 is changed so that unevenness in brightness on the inner peripheral surface 3g of the irradiation unit 3 is reduced.

  The propagation direction of the light L1 can be appropriately changed by changing the angle formed by the reflective surface 13a1 and the light L1 reflected by the reflective surface 3h1, and the arrangement position of the reflective surface 13a1.

  The hole 13b is provided in the vicinity of the connection portion between the incident portion 3d and the second irradiation portion 3c. The hole 13b does not open on the side surface 3d2 side of the incident part 3d and the inner peripheral surface 3g of the irradiation part 3 (outside and inside of the irradiation part 3 in plan view). The hole 13b penetrates the illumination unit 13 (second irradiation unit 3c) in the thickness direction. Therefore, the inside of the hole 13b is filled with gas (generally air) included in the environment in which the illumination unit 13 is provided. The hole 13b has a reflective surface 13b1. The reflective surface 13b1 reflects light according to the difference between the refractive index of the material of the illumination unit 3 and the refractive index of the gas. The reflection surface 13b1 is provided at a position where the light L1 reflected by the reflection surface 3i1 enters. The angle formed by the reflection surface 13b1 and the light L1 reflected by the reflection surface 3i1 is preferably an angle that allows the incident light L1 to be totally reflected. If the reflection surface 13b1 totally reflects the incident light L1, the utilization efficiency of the light incident on the reflection surface 13b1 can be improved.

  The light L1 incident on the reflecting surface 13b1 is reflected by the reflecting surface 13b1 and the propagation direction is changed. At this time, the propagation direction of the light L1 is changed so that unevenness in brightness on the inner peripheral surface 3g of the illumination unit 13 is reduced.

The propagation direction of the light L1 can be appropriately changed by changing the angle formed by the reflection surface 13b1 and the light L1 reflected by the reflection surface 3i1 and the arrangement position of the reflection surface 13b1.
In addition, although the hole parts 13a and 13b which exhibit a triangular shape in planar view were illustrated, if it has the reflective surfaces 13a1 and 13b1, there will be no limitation in particular in the shape of the hole parts 13a and 13b.

Moreover, the arrangement | positioning position and number of incident parts can be changed suitably.
In this case, the positions and number of the concave portions and the hole portions can be changed as appropriate according to the positions and number of the incident portions.
FIG. 9 is a schematic diagram for illustrating an illumination unit 23 according to another embodiment.
In the case of the irradiation part 13 described above, the incident part 3d, the concave part 3i, and the hole part 13b are provided on one end side in the longitudinal direction of the irradiation part 13, and the incident part 3b, the concave part 3h, and the hole part 13a. Is provided on the other end side in the longitudinal direction of the irradiation unit 13.
Further, the incident portion 3d, the concave portion 3i, and the hole portion 13b are provided on one end side in the short direction of the irradiation portion 13, and the incident portion 3b, the concave portion 3h, and the hole portion 13a are short of the irradiation portion 13. It is provided on the other end side in the hand direction.

On the other hand, in the case of the illumination part 23, as shown in FIG. 9, the incident part 3d, the recessed part 3i, and the hole part 13b, the incident part 3b, the recessed part 3h, and the hole part 13a It is provided on the same end side in the longitudinal direction.
Further, the incident portion 3d, the concave portion 3i, and the hole portion 13b are provided on one end side in the short direction of the illumination portion 23, and the incident portion 3b, the concave portion 3h, and the hole portion 13a are short of the irradiation portion 23. It is provided on the other end side in the hand direction.
When the direction of the light L incident from the incident unit 30b and the direction of the light L ′ incident from the incident unit 30d are opposite to each other as in the configuration of FIG. 5, for example, the occupant is from one end in the longitudinal direction of the irradiation unit 30. When the irradiation unit 30 is visually recognized, the irradiation unit that guides light traveling toward the passenger may feel bright, and the irradiation unit that guides light away from the passenger may feel dark.
In the configuration of FIG. 9, the direction of light incident from the incident part 3 b and the incident part 3 d, that is, the direction of light viewed from one end in the longitudinal direction of the irradiation part 23 can be made uniform. It is possible to improve the uniformity of the apparent light of the irradiating unit 23 that is felt.

FIG. 10 is a schematic diagram for illustrating an illumination unit 33 according to another embodiment.
As shown in FIG. 10, in the case of the illumination part 33, the incident part 3d, the recessed part 3i, and the hole part 13b, and the incident part 33b, the recessed part 3k, and the hole part 13d are one side in the longitudinal direction of the illumination part 33. Is provided on the end side.
The incident portion 3b, the concave portion 3h, and the hole portion 13a, and the incident portion 33a, the concave portion 3j, and the hole portion 13c are provided on the other end side in the longitudinal direction of the illumination portion 33.
The incident portion 3d, the concave portion 3i, and the hole portion 13b, and the incident portion 33a, the concave portion 3j, and the hole portion 13c are provided on one end side in the lateral direction of the illumination portion 33.
The incident portion 3b, the concave portion 3h, and the hole portion 13a, and the incident portion 33b, the concave portion 3k, and the hole portion 13d are provided on the other end side in the lateral direction of the illumination portion 33.
Since the direction of the light incident from the incident part 3d and the incident part 33b, that is, the direction of the light with respect to the occupant visually recognized from one end in the longitudinal direction of the irradiating part 33 can be aligned, the appearance of the irradiating part 33 felt by the occupant The uniformity of light can be improved.
Moreover, since the direction of the light incident from the incident part 3b and the incident part 33a, that is, the direction of the light with respect to the occupant viewed from one end in the longitudinal direction of the irradiating part 33 can be aligned, the irradiating part 33 that the occupant feels. It is possible to improve the uniformity of the apparent light.

Moreover, in the above, although the container holder 100 which can hold | maintain up to two containers was illustrated, it can also be set as the container holder which can hold | maintain one container or three or more containers.
FIG. 11 is a schematic perspective view for illustrating a container holder 110 that can hold one container.
FIG. 12 is a schematic diagram for illustrating the irradiation unit 43 provided in the container holder 110.

As shown in FIGS. 11 and 12, the container holder 110 is provided with a cover portion 111, a holding portion 112, and the lighting device 11.
The lighting device 11 is provided with the light emitting unit 2 and the lighting unit 43.
Except for holding one container, it can be the same as the container holder 100 and the lighting device 1 described above.
Therefore, the detailed description regarding the container holder 110 is omitted.

  Moreover, although the incident part 3b provided in the outer peripheral surface of the irradiation part 3 was illustrated, the incident part 3b is provided in the at least one end surface of the side in which the cover part 101 and the holding | maintenance part 102 of the irradiation part 3 are provided. May be. That is, it is only necessary that the incident part has one end provided on the irradiation part and the other end faces the light emitting part.

  FIG. 13 is a schematic perspective view for illustrating an arrangement form of incident portions according to another embodiment. As shown in FIG. 13, the incident part 3 b may be provided on the end surface of the irradiation part 3 on the side where the holding part 102 is provided.

  As mentioned above, although several embodiment of this invention was illustrated, these embodiment is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, changes, and the like can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and equivalents thereof. Further, the above-described embodiments can be implemented in combination with each other.

  DESCRIPTION OF SYMBOLS 1 Illuminating device, 2 light emission part, 2a housing | casing part, 2b light emitting element, 3 illumination part, 3a 1st irradiation part, 3a1 inner peripheral surface, 3b incident part, 3c 2nd irradiation part, 3d incident part, 3e 1st 3 irradiation part, 3f 4th irradiation part, 3g inner peripheral surface, 3h concave part, 3h1 reflective surface, 3i concave part, 3i1 reflective surface, 3j concave part, 3k concave part, 11 illumination device, 13 illumination part, 13a hole part, 13a1 Reflection surface, 13b hole portion, 13b1 reflection surface, 13c hole portion, 13d hole portion, 23 illumination portion, 33 illumination portion, 33a incidence portion, 33b incidence portion, 43 illumination portion, 100 container holder, 101 cover portion, 101a hole portion , 102 holding part, 110 container holder, 111 cover part, 112 holding part

Claims (6)

An irradiating portion that has an annular shape and irradiates light from the inner peripheral surface;
One end is provided on the outer peripheral surface of the irradiation unit, and the other end is provided at a position separated from the irradiation unit;
A light emitting part having a light emitting element and provided opposite to the other end of the incident part;
A recess having a first reflecting surface for reflecting a part of the light introduced into the incident portion, provided in the vicinity of a connection portion between the incident portion and the irradiation portion, and opening in an outer peripheral surface of the irradiation portion When;
A lighting device comprising: Light that is introduced into the incident part and does not enter the first reflecting surface propagates in the first direction through the irradiation part,
2. The concave portion reflects light incident on the first reflecting surface by the first reflecting surface and propagates the inside of the irradiation unit in a second direction different from the first direction. The lighting device described.   The lighting device according to claim 1, wherein the first reflecting surface totally reflects the incident light.   4. The device according to claim 1, further comprising a hole portion provided in the vicinity of a connection portion between the incident portion and the irradiation portion and having a second reflection surface that reflects the light reflected by the first reflection surface. The illuminating device as described in any one.   The lighting device according to claim 4, wherein the second reflecting surface totally reflects incident light. A cover having a hole for inserting the container;
A holding portion having an opening for inserting the container and provided so that the opening faces the hole of the cover portion;
The illumination device according to any one of claims 1 to 5, provided between the cover portion and the holding portion;
A container holder.

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