JP5944942B2 - lighting equipment - Google Patents

Description

  The present invention relates to a lighting fixture.

  Conventionally, the lighting fixture provided with several LED as a light source is known (for example, refer patent document 1).

  Patent Document 1 discloses a lighting fixture having a light source arranged such that a plurality of LEDs are arranged in a circle to form an LED group, and the plurality of LED groups are concentrically arranged. In the luminaire of Patent Document 1, light distribution is controlled by passing light from a plurality of LED groups through two lenses.

International Publication No. 2011/144597

  However, in the luminaire disclosed in Patent Document 1, light distribution control is performed by collectively making light from a plurality of LEDs incident on a lens. Therefore, some of the plurality of LEDs are controlled as spot light. Or it cannot be controlled as diffused light. That is, even if a plurality of light sources are provided, it is not possible to divide the light sources and control light distribution independently as spot light or diffused light.

  Accordingly, the present invention has been made in view of the above problems, and is a lighting fixture having a plurality of light sources, which divides the light source and independently controls light distribution as spot light or diffused light. The purpose is to provide.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, the lighting fixture disclosed in this application is
A luminaire comprising a plurality of light sources,
The light source is
A first light source disposed in the center;
A second light source disposed around the first light source,
A lens disposed opposite the first light source;
A translucent member disposed to face the second light source;
A cylindrical partition that partitions the first light source and the second light source and accommodates the lens;
A substantially cylindrical holding member for holding the lens and the translucent member in the partition wall;
The second light source includes a reflecting member that is disposed on a side away from the first light source and reflects light from the second light source ,
The inner peripheral surface of the partition wall reflects a part of the light emitted from the first light source,
The outer peripheral surface of the holding member reflects a part of the light emitted from the second light source .

In the lighting fixture disclosed in the present application,
The translucent member is preferably disposed around the lens and formed in a mortar shape.

In the lighting fixture disclosed in the present application,
The translucent member preferably diffuses light passing therethrough.

In the lighting fixture disclosed in the present application,
It is preferable that at least one of the first light source and the second light source includes an LED.

  According to the present invention, the light source can be divided and light distribution can be controlled independently as spot light or diffused light.

The perspective view which looked at the embedded type lighting fixture which concerns on one Embodiment of this invention from diagonally downward. The perspective view which looked at the embedded lighting fixture from diagonally upward. The top view which shows an embedded type lighting fixture. It is a figure which shows the state which attached the lamp main body to the attachment hole, and is the sectional view on the AA 'line of FIG. The bottom view which looked at the lamp body from the bottom. The figure which shows arrangement | positioning of the LED element of a board | substrate. It is the perspective view which shows a reflective member, (a) The perspective view seen from diagonally downward, (b) The perspective view seen from diagonally upward. It is the perspective view which shows a panel, (a) The perspective view seen from diagonally downward, (b) The perspective view seen from diagonally upward. It is a perspective view which shows a lens holder, (a) The perspective view seen from diagonally downward, (b) The perspective view seen from diagonally upward. Explanatory drawing for demonstrating the light distribution control by a panel. Explanatory drawing explaining the light distribution control by a partition and a lens holder. Explanatory drawing explaining the light distribution control by a lens holder. Explanatory drawing explaining the light distribution control by a reflection member and a lens holder.

  An embedded lighting apparatus 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 13. As shown in FIG. 4, the embedded lighting fixture 100 is a downlight that is formed in a ceiling C serving as a mounting surface, for example, embedded in a circular mounting hole H. In the following description, the vertical direction of the embedded lighting device 100 will be described as the vertical direction in the state where the embedded lighting device 100 is installed on the ceiling C (the vertical direction in FIG. 4). A direction perpendicular to the vertical direction will be described as a radial direction. In the description of the present embodiment, a state in which the embedded lighting device 100 and the like are viewed from above is a plan view. A state in which the embedded lighting device 100 and the like are viewed from a direction orthogonal to the vertical direction is referred to as a side view. A state in which the cross-sectional shape of the embedded lighting device 100 or the like is viewed is referred to as a cross-sectional view.

  As shown in FIGS. 1 and 2, the embedded lighting device 100 mainly includes a lamp body 11 and a power supply unit 51. The lamp body 11 is connected to the power supply unit 51 by a holding member (not shown), and holds the power supply unit 51 on the side of the lamp body 11.

  The lamp body 11 includes a light source part 21, a heat sink 41, a flange part 35, and a mounting spring 71.

  The light source unit 21 is a part that emits light toward the irradiation surface side of the embedded lighting fixture 100. As shown in FIG. 4, the light source unit 21 is provided inside the opening 11 a of the lamp body 11 and in the light source arrangement unit 44 of the heat sink 41, and includes the substrate 22, the lens 29, the reflection member 23, and the panel. 24. A lens holder 30 is provided.

As shown in FIG. 6, the board | substrate 22 is an LED module provided with the LED element which is a some point light source on the mounting surface processed into disk shape. As an LED element, it has the 1st LED element 31 and the 2nd LED element 32 arrange | positioned around this 1st LED element 31. As shown in FIG. The first LED element 31 is an LED having a circular light emitting surface arranged at the center of the substrate 22. The second LED element 32 is an LED in which a plurality of (in this embodiment, 12) second LED elements 32a are concentrically arranged at substantially equal intervals around the optical axis L1 (see FIG. 4) of the first LED element 31. is there. The first LED elements 31 are arranged so as to correspond to the light source holes 23 a for the first LED elements of the reflecting member 23. The second LED elements 32 (the plurality of second LED elements 32a) are arranged at positions corresponding to the plurality of light source holes 23b for the second LED elements of the reflecting member 23. The substrate 22 is arranged such that the back surface of the mounting surface is in contact with the bottom surface 44a of the light source arrangement portion 44 of the heat sink 41, and is attached to the heat sink 41 with an attachment member such as a screw. The substrate 22 is electrically connected to the power supply unit 51 by an electric wire (not shown). The first LED element 31 is provided with a lens 29 at a position facing the light exit surface.
In this embodiment, a surface-mount type LED element is used as the light source. However, the type of the light source is not limited to the LED element, and can be realized by, for example, a COB type light emitting module or an organic EL element (OLED). It is. That is, the 1st LED element 31 is an example of the 1st light source of this invention. The 2nd LED element 32 is an example of the 2nd light source of this invention.
Moreover, the board | substrate 22 may be attached to the light source arrangement | positioning part 44 via a heat conductive sheet (not shown) and thermal radiation grease, and, thereby, higher heat dissipation can be obtained.
Further, although the number of the first LED elements 31 is one in the present embodiment, a plurality of the first LED elements 31 may be provided.
Moreover, the LED element of the same color temperature may be employ | adopted for the 1st LED element 31 and the 2nd LED element 32, and the LED element of a different color temperature may be employ | adopted. When LED elements having different color temperatures are employed, for example, LED elements having a color temperature of around 5000 Kelvin (so-called lunch white) are adopted as the first LED elements 31, and color temperatures of around 3000 Kelvin (so-called so-called second LED elements 32). A light bulb color) LED element can be employed.

The lens 29 is an optical member for controlling the light distribution of the light (emitted light) emitted from the first LED element 31. Specifically, the lens 29 is a medium-angle light distribution lens that distributes light (emitted light) emitted from the first LED elements 31 at a medium angle. The lens 29 is formed by applying a highly transparent and chemically stable optical material (for example, acrylic resin, polycarbonate, glass, or the like). Moreover, although the lens 29 of this embodiment is a collimating lens, it is not restricted to this, You may form in another shape according to a use. As shown in FIG. 4, the lens 29 has a substantially bullet shape with a lower end having a large diameter surface and an upper end having a small diameter surface. The lens 29 has, as an incident surface from the first LED element 31 that is a light source, an incident concave portion 29a provided to face the first LED element 31, and a diameter-expanded portion that increases in diameter from the upper end periphery of the incident concave portion 29a downward. 29b. The bottom surface of the incident concave portion 29 a has a convex curved surface shape toward the first LED element 31. The lens 29 has, as an exit surface, an exit recess 29c and a flat exit ring surface 29d formed in an annular shape around the exit recess 29c. The lens 29 has a flange 29e that protrudes radially outward from the outer peripheral surface on the lower end side. The lens 29 is positioned by accommodating the upper end side (the smaller diameter side of the lens 29) in the partition wall portion 23e, and the flange portion 29e is locked to the lower end of the partition wall portion 23e. The first LED element 31 is disposed close to the upper end side (the small diameter side of the lens 29) of the lens 29 through the light source hole 23a, and is disposed to face the bottom surface of the incident recess 29a. The optical axis L1 is disposed coaxially with the axis of the lens 29. The lens 29 can collect the light incident on the incident surface from the first LED element 31 so as to have a predetermined irradiation angle. That is, the lens 29 condenses the light from the first LED element 31 into spot light.
In the present embodiment, a medium-angle light distribution lens is used as the lens 29, but it is not particularly limited. For example, any lens capable of obtaining spot light may be used, and a narrow-angle light distribution lens having an irradiation angle narrower than that of the medium-angle light distribution lens can be used. Further, instead of the lens 29, for example, a disk-shaped or hemispherical transparent cover, for example, a disk-shaped or hemispherical transparent cover may be provided. In addition, the exit annular surface 29d of the lens 29 may be subjected to light diffusion processing (texture processing, erasing processing, etc.) for diffusing light from the first LED element 31, thereby causing uneven illuminance and hue separation phenomenon. Can be reduced.

In the second LED element 32, the reflecting member 23 is disposed on the side away from the first LED element 31, and is disposed at a position where the light from the second LED element 32 can be reflected. The reflection member 23 is a member that independently reflects the light from the first LED element 32 and the light from the second LED element 32. The reflection member 23 is a member that separates the panel 24 and the substrate 22 at a predetermined interval. As shown in FIG. 7, the reflecting member 23 is a substantially cylindrical member having one end opened. The reflection member 23 is formed of a resin material or the like. The reflecting member 23 is housed in the light source arrangement portion 44 and attached to the lamp body 11 by a screw member 60 that is screwed into a screw hole 61 arranged in the light source arrangement portion 44. The reflection member 23 has a bottom surface portion 23c formed in a disc shape, and a peripheral wall portion 23d connected to the bottom surface portion 23c is formed in a substantially bowl shape that gradually spreads as the distance from the bottom surface portion 23c increases. The inner surface of the reflecting member 23 is a reflecting surface that reflects light emitted from the LED element. A circular light source hole 23a that exposes the first LED element 31 is formed in the center portion of the bottom surface portion 23c formed in a disc shape, and the second LED elements 32 (a plurality of concentric circles centering on the light source hole 23a) are formed. A plurality of light source holes 23b, 23b,... Exposing the second LED elements 32a, 32a,. Around the circular light source hole 23a, a cylindrical partition wall 23e protruding downward from the bottom surface 23c and having an open lower end is formed. That is, the circular light source hole 23a is formed at the center of the bottom surface portion 23c in the partition wall portion 23e.
In the reflecting member 23 of this embodiment, as shown in FIG. 7, a part of the upper end corner of the reflecting member 23 is cut in order to insert an electric wire (not shown) electrically connected to the substrate 22. The opening 23g is provided without it. Therefore, in the vicinity of the opening 23g, a light source hole 23ba formed in a semicircular shape is provided as a light source hole for exposing the second LED element 32.

  The partition wall 23e partitions the first LED element 31 and the second LED element 32. The light source hole 23b is formed concentrically around the light source hole 23a in the bottom surface part 23c between the partition wall part 23e and the peripheral wall part 23d. The partition wall portion 23 e is a portion that accommodates the lens 29 and positions the lens 29 at the central portion in the light source arrangement portion 44 of the lamp body 11. Although details will be described later, the reflecting member 23 receives light from the first LED element 31 entering the reflecting member 23 through the light source hole 23a and from the second LED element 32 entering the reflecting member 23 through the light source hole 23b. It is possible to prevent light from interfering with each other by the partition wall portion 23e. Moreover, the reflection member 23 reflects the light which goes to the side among the light emitted from the second LED element 32 by the reflection surface, and controls the light distribution so as to go downward. That is, the light emitted from the second LED element 32 is efficiently collected by reflecting the light emitted in the direction other than the lower side of the second LED element 32 by the reflecting member 23 having the reflecting surface.

  The partition wall portion 23 e is a member that is disposed on the side of the first LED element 31 that is away from the second LED element 32 and reflects light from the first LED element 31. The partition wall portion 23e reflects light from the first LED element 31 by the inner peripheral surface.

  In addition, in this embodiment, although the shape of the reflection member 23 was formed in the substantially bowl shape, it does not specifically limit. For example, as the shape of the reflecting member 23, the peripheral wall portion 23d of the reflecting member 23 may be formed in a parabolic shape or an inclined surface shape that spreads downward.

  On the upper part of the reflecting member 23, a locking projection 23f is provided so as to position the reflecting member 23 with respect to the lamp body 11 (light source arrangement portion 44) by locking in the locking hole 45 of the lamp body 11. Yes.

The reflecting member 23 is made of a polycarbonate resin having a high reflectance.
In the present embodiment, the reflecting member 23 is made of polycarbonate resin, but is not particularly limited. For example, other resin members or metal members can be used. In order to enhance reflection, the reflective surface of the reflective member 23 may be coated with aluminum vapor deposition or silver vapor deposition.

The panel 24 is a member disposed around the lens 29 and formed in a mortar shape (see FIG. 8). The panel 24 is a translucent member that is disposed to face the second LED element 32 and covers the lower side of the second LED element 32. The panel 24 is a translucent member that closes from the outer periphery of the lower end of the lens 29 to the opening 11 a of the lamp body 11 and transmits and diffuses light from the second LED element 32 disposed in the light source arrangement portion 44. is there. The panel 24 is formed of a light-transmitting resin material (for example, acrylic resin) or a glass material. The panel 24 is formed in an annular shape in plan view so as to increase in diameter downward with the lens 29 and the lens holder 30 as the center. As shown in FIGS. 4 and 8, the panel 24 has an opening 24 a, a locking portion 24 b, and a peripheral wall portion 24 c that is substantially C-shaped in cross section. The panel 24 has a circular opening 24a at the center. The opening 24 a is provided with a locking portion 24 b that is substantially L-shaped in cross-section and that locks the step 30 c of the lens holder 30. The peripheral wall portion 24c is formed in a parabolic shape extending from the locking portion 24b and expanding downward. The peripheral wall 24c is a surface that transmits and diffuses the light emitted from the second LED element 32. The panel 24 is positioned on the lamp body 11 by the outer peripheral end being locked to the step portion 11 b in the vicinity of the opening 11 a of the lamp body 11. Thus, with the outer peripheral end of the panel 24 positioned, the locking portion 24b is locked to the step portion 30c of the lens holder 30, and the lens holder 30 is fitted to the partition wall portion 23e. The panel 24 can emit diffused light from the emission surface of the panel 24 by allowing the light from the second LED element 32 to pass therethrough. Specifically, the panel 24 can emit diffused light with a wide-angle light distribution having a wider irradiation angle than the spot light with a medium-angle light distribution obtained by the lens 29.
The shape seen from below the panel 24 is not limited to the circular shape as shown in FIG. 5 or the like, but may be a polygon such as a quadrangle, or a shape that can be attached to the opening shape of various attachment holes. .

  The lens holder 30 is a holding member that holds the lens 29 and the reflecting member 23 on the partition wall 23e. As shown in FIG. 9, the lens holder 30 is a substantially cylindrical member having both ends open. The lens holder 30 has a cylindrical wall portion 30a, a locking portion 30b, a stepped portion 30c, and an engagement hole 30d. The inner diameter of the cylindrical wall portion 30a is larger than the outer shape of the partition wall portion 23e included in the reflecting member 23, and can be fitted to the outer peripheral surface of the partition wall portion 23e. The upper end side of the cylindrical wall 30a can be inserted into the opening 24a of the panel 24. At the lower end of the cylindrical wall portion 30a, a locking portion 30b that protrudes radially inward and locks the flange portion 29e of the lens 29 is formed. A lower end side of the outer peripheral surface of the lens holder 30 protrudes outward in the radial direction, and a step portion 30c is formed to lock the locking portion 24b of the panel 24. The engagement hole 30d is a hole that is cut out in a substantially L shape in a side view and that locks the locking protrusion 23f of the reflecting member 23. In the lens holder 30, the lens 29 is accommodated in the partition wall portion 23e, and the outer peripheral surface of the panel 24 is locked to the step portion 11b of the lamp body 11, and the outer peripheral surface of the partition wall portion 23e and the opening portion 24a of the panel 24. The upper end of the cylindrical wall portion 30a is inserted into the gap formed between and the flange portion 29e of the lens 29 is sandwiched between the lower end of the partition wall portion 23e and the locking portion 30b, and the panel 24 is formed by the step portion 30c. The locking portion 24b is locked. At this time, the locking projection 23f is guided to the middle in the vertical direction along the engagement hole 30d of the lens holder 30, and the lens holder 30 is fitted to the outer periphery of the partition wall 23e so that the lens holder 30 is engaged with the partition wall 23e. , The locking projection 23f moves in the horizontal direction along the engagement hole 30d of the lens holder 30 and is guided to the locking end 30e. As described above, the lens 29 and the panel 24 are fixed to the lamp body 11 by the engagement hole 30 d of the lens holder 30 and the locking protrusion 23 f of the reflection member 23.

  The lens holder 30 constitutes a wall portion that partitions between the first LED element 31 and the second LED element 32 by fitting into the partition wall portion 23e of the reflecting member 23. The wall portion is a structure that shields light.

  The heat sink 41 is a heat dissipation member made of a metal material such as aluminum having high thermal conductivity. The heat sink 41 includes a base portion 42, a heat radiation fin 43, a light source arrangement portion 44, and a spring attachment portion 48 to which an attachment spring 71 is attached.

  The base 42 is a part that is substantially cylindrical with a bottom. The base part 42 has a disk-shaped upper plate part 42a at the upper part. The upper plate portion 42a is formed with a plurality of heat radiation fins 43, 43,. As shown in FIG. 4, a light source arrangement part 44 for arranging the light source part 21 in a concave shape is formed on the lower end side of the base part 42.

  The spring attachment portion 48 is a portion for attaching the attachment spring 71 to the heat sink 41. A plurality (two in this embodiment) of spring mounting portions 48 are provided so as to be substantially evenly arranged on the periphery of the base portion 42 of the heat sink 41. The spring attachment portion 48 is for abutting the attachment spring 71 and attaching it with a screw 57.

  The flange portion 35 is a flange portion that protrudes radially outward from the outer peripheral edge of the lower portion of the lamp body 11 and is formed in an annular shape. The flange portion 35 is a portion that covers the peripheral portion of the mounting hole H in a state where the embedded lighting device 100 is installed in the mounting hole H of the ceiling C. On the upper surface of the flange portion 35, when the lamp body 11 is mounted in the mounting hole H, a frame packing 37 having an annular shape in plan view for closing the gap between the lamp body 11 and the peripheral edge of the mounting hole H is provided. . The flange portion 35 covers the peripheral edge portion of the mounting hole H via the frame packing 37 on the lower surface side of the ceiling C.

The attachment spring 71 is a fixing means for embedding and attaching the embedded lighting device 100 in the attachment hole H of the ceiling C. The attachment spring 71 is disposed on a spring attachment portion 48 that is substantially equally disposed on the periphery of the base portion 42. The attachment spring 71 is a plate spring formed by bending and bending a middle portion of a plate-like metal member such as a stainless steel material at a plurality of locations. As shown in FIG. 1, the mounting spring 71 is a leaf spring formed in a substantially V shape, and a base end portion is in contact with a spring mounting portion 48 of the heat sink 41 and is fixed by a screw 57 and a free end. The part extends to the side of the lamp body 11. When the embedded lighting device 100 is installed in the mounting hole H of the ceiling C, the mounting spring 71 is pressed between the flange portion 35 by pressing the peripheral edge of the mounting hole H by the elastic force that the mounting spring 71 tries to spread. Then, the ceiling C is clamped, and the embedded lighting device 100 is fixed to the ceiling C.
In addition, about the shape of an attachment spring, an attachment position, a number, etc., it is not limited to the thing of this embodiment.

  The power supply unit 51 is a power supply device that supplies power to the LED elements (the first LED element 31 and the second LED element 32) included in the light source unit 21 to light the LED elements. The power supply unit 51 accommodates a power supply circuit in which a plurality of electronic components are mounted on a printed wiring board processed into a rectangular shape in a box-shaped power supply case. The power supply unit 51 converts an alternating current supplied from an external commercial power source into a predetermined direct current, and converts the converted current to a plurality of LED elements (first LED element 31 and second LED element 32) mounted on the substrate 22. It is for supply. The power supply unit 51 is electrically connected to the terminal block 53 through wiring (not shown). The terminal block 53 is disposed on one side surface of the power supply unit 51. When the embedded lighting device 100 is attached to the ceiling C, the power supply unit 51 is connected to an external commercial power source by connecting the terminal block 53 and an external commercial power source (not shown) on the back side of the ceiling by wiring (not shown). Electrically connected. The power supply unit 51 and the substrate 22 are electrically connected by wiring (not shown).

  The light distribution control in the embedded lighting fixture 100 of the present embodiment described above will be described with reference to FIGS.

First, the structure which improves the light distribution characteristic in the embedded lighting fixture 100 will be described.
As shown in FIG. 10, a part of the light emitted from the second LED element 32 (the plurality of second LED elements 32a) passes through the panel 24 (the peripheral wall portion 24c). The light passing through the vicinity of the outer peripheral edge of the panel 24 is diffused by the panel 24, emitted as diffused light toward the radially inner side of the panel 24 (the direction indicated by the dotted arrow in FIG. 10), and travels radially outward. As described above, the panel 24 can control light distribution through a wide angle. Further, in the embedded lighting device 100 of the present embodiment, the outer peripheral edge portion of the panel 24 and the lower end surface of the lamp body 11 (flange portion 35) are formed so as to be a continuous curve shape or substantially flush with each other. Therefore, it does not hinder the outgoing light from the panel 24 from spreading outward in the radial direction of the panel 24. As a result, as shown in FIG. 10, even when attached to the ceiling C, light spreading radially outward from the panel 24 can be guided to the ceiling surface of the ceiling C, and the ceiling surface can be illuminated brightly. That is, according to the embedded lighting fixture 100, the emission surface of the panel 24 and the surface on the indoor space side of the lamp body 11 adjacent to the panel 24 are formed in a continuous substantially curved shape. . Thereby, it becomes a wide angle light distribution which spreads toward the radial direction outer side of the lamp main body 11, and can improve the light distribution characteristic of illumination.

Next, a structure for preventing mixing of the emitted light of the first LED element 31 and the second LED element 32 will be described.
As shown in FIG. 11, a part of the light emitted from the first LED element 31 is reflected by the inner peripheral surface of the cylindrical partition wall 23 e included in the reflecting member 23 and proceeds to the lens 29 side. On the other hand, a part of the light emitted from the second LED element 32 is reflected by the outer peripheral surface of the cylindrical wall portion 30 a included in the lens holder 30. Thus, for example, by providing the wall portion configured by the partition wall portion 23e and the cylindrical wall portion 30a, the light emitted from the first LED element 31 and the light emitted from the second LED element 32 do not mix with each other. That is, according to the embedded illumination fixture 100, it is possible to independently control light distribution for a part of the light source as spot light such as medium-angle light or diffused light such as wide-angle light. Accordingly, when the first LED element 31 is turned on and the second LED element 32 is turned off, the light emitted from the first LED element 31 is radially outward from the wall portion configured by the partition wall portion 23e and the cylindrical wall portion 30a. Since it does not proceed, the panel 24 does not appear to emit light due to the light emitted from the first LED element 31.
Note that the light emitted from the first LED element 31 and the light emitted from the second LED element 32 do not mix with each other, which is a phenomenon in at least the radial region of the wall portion, and from the first LED element 31 through the lens 29. The light emitted downward and the light emitted downward from the second LED element 32 via the panel 24 may be mixed at least partially in the lower region of the lamp body 11.

Next, a structure in which light emitted by the first LED element 31 does not enter the back side of the panel 24 will be described.
As shown in FIG. 12, the outgoing light emitted from the outer peripheral end of the exit surface side of the lens 29 does not pass through the panel 24 and exit to the back side of the panel 24 because the lens holder 30 is disposed. That is, by providing the lens holder 30, it is possible to separate the light emitted from the first LED element 31 exiting from the exit surface of the lens 29 and the light emitted from the second LED element 32 exiting from the exit surface (surface) of the panel 24. That is, according to the embedded lighting fixture 100, the light source can be divided and light distribution can be controlled independently as spot light or diffused light.

  In the embedded lighting device 100 of the present embodiment, as shown in FIG. 13, the reflecting member 23 is inserted into the engaging hole 30 d of the lens holder 30 in a state where the lens 29 and the panel 24 are supported by the lens holder 30. And the lens 29 and the panel 24 are attached to the lamp body 11 by the lens holder 30. Thereby, the lens 29 and the panel 24 can be assembled to the lamp body 11 by the lens holder 30 which is one holding member, and the number of parts can be reduced.

  Further, in the embedded lighting fixture 100 of the present embodiment, as shown in FIG. 13, in the space defined by the reflecting member 23, the wall portion (the partition wall portion 23 e and the cylindrical wall portion 30 a), and the panel 24, The light emitted from the 2LED elements 32 can be emitted from the panel 24 while being reflected. Thus, according to the embedded lighting fixture 100, the light source can be divided and the light distribution can be controlled independently as spot light or diffused light.

  According to the present invention, it is possible to divide a light source and control light distribution so as to be spot light or diffused light, and to perform illumination in which spot light and diffused light are combined with a single lighting fixture.

DESCRIPTION OF SYMBOLS 11 Lamp main body 21 Light source part 23 Reflective member 23e Partition part 24 Panel 29 Lens 30 Lens holder 30a Cylindrical wall part 31 1st LED element (1st light source)
32 Second LED element (second light source)
100 Recessed lighting fixture C Ceiling H Mounting hole

Claims (4)

A luminaire comprising a plurality of light sources,
The light source is
A first light source disposed in the center;
A second light source disposed around the first light source,
A lens disposed opposite the first light source;
A translucent member disposed to face the second light source;
A cylindrical partition that partitions the first light source and the second light source and accommodates the lens;
A substantially cylindrical holding member for holding the lens and the translucent member in the partition wall;
The second light source includes a reflecting member that is disposed on a side away from the first light source and reflects light from the second light source ,
The inner peripheral surface of the partition wall reflects a part of the light emitted from the first light source,
The outer peripheral surface of the holding member reflects a part of light emitted from the second light source . The lighting fixture according to claim 1 ,
The translucent member is a lighting fixture that is disposed around the lens and is formed in a mortar shape. The lighting apparatus according to claim 1 or 2 ,
The translucent member diffuses light passing therethrough. It is a lighting fixture as described in any one of Claims 1-3 ,
At least one of the first light source and the second light source includes an LED.

Images