JP2017033953A - Lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting device capable of increasing a range of presentable luminous colors and presenting a proper optical space that is suitable for each life scene.SOLUTION: A lighting device includes a white light source 22 of bulb color and daylight color as luminous color, and a primary color light source emitting green color and blue color, and as compared with the case where only the white light source is turned on, illumination light turned on in a dedicated mode turning on the white light source and the primary color light source has higher correlation color temperature.SELECTED DRAWING: Figure 6

Description

  Embodiments described herein relate generally to a lighting device that can change the light color of illumination using a light emitting element such as a light emitting diode (hereinafter referred to as LED) as a light source.

  Recently, along with higher output and higher efficiency of LEDs, lighting devices that use LEDs as light sources and can be used indoors or outdoors can be expected. This illuminating device is obtained by mounting a plurality of LEDs on a substrate so as to obtain a predetermined brightness, and is used as, for example, base illumination attached to a ceiling surface or the like.

  On the other hand, with the diversification of lifestyles, the functions required of these lighting devices include not only simply illuminating the surroundings brightly, but also considering the influence of the surrounding environment and light on the living body, etc. It is desired to produce an appropriate light space suitable for a living scene, such as satisfying comfort.

  For this reason, there has been proposed an LED that emits light of daylight color and light bulb color as a light source, and adjusts the brightness and light color to obtain illumination suitable for a living scene.

  There is also known an illumination device in which a plurality of LEDs having different emission colors are used as light sources, the light emission intensities of the plurality of light sources are respectively adjusted, and the color temperature is changed by mixing these lights. In this illuminating device, a blue LED, a green LED, and a light bulb color LED having different emission colors are used as light sources to adjust their emission intensity.

  Furthermore, what adjusts these emitted light intensity using red LED, green LED, and blue LED from which luminescent color differs as a light source is known.

LED Ceiling Light “EVERLEDS” Series Released | Press Releases | News | Panasonic Corporate Information | panasonic data.dir / jn1101 26-2 / jn110126-2.html)

JP 2009-111080 A JP 2010-238407 A

  However, in the lighting device as described above, the range of light colors that can be expressed is narrow, that is, the light emission spectrum that can be expressed is poor, and it may be difficult to produce an appropriate light space that matches the living scene. .

  The present invention has been made in view of the above problems, and provides an illumination device that can widen the range of light colors that can be expressed and can produce an appropriate light space according to a living scene. For the purpose.

  An illuminating device according to an embodiment of the present invention is an illuminating device including: a white light source whose emission colors are a light bulb color and a daylight color; and a primary color light source that emits primary color light. The illuminating device includes only the white light source. It is possible to control lighting, and a dedicated mode for lighting the white light source and the primary color light source is provided, and the illumination light in the dedicated mode has higher color rendering than when only the white light source is turned on. It is set as follows.

  According to the embodiment of the present invention, it is possible to provide a lighting device that can widen the range of light colors that can be expressed and can produce an appropriate light space according to a living scene. Become.

It is a perspective view which shows the illuminating device which concerns on embodiment of this invention. It is a disassembled perspective view of the front side which shows the illuminating device. In the same illuminating device, it is a top view which removes and shows a shade and a light source part cover. It is a perspective view of the back side which shows the illuminating device. It is sectional drawing which shows the state which attached the lighting device to the ceiling surface. It is a longitudinal cross-sectional view which shows the same illuminating device. It is a graph which shows the emission spectrum of a light emitting element. FIG. 6 is a chromaticity coordinate diagram showing an evaluation result of “Azayaka” mode. It is a graph which shows the evaluation result of "study" mode. It is a graph which shows the evaluation result of "healing" mode. It is a graph which shows the evaluation result of "theater" mode.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 to 11. 1 to 6 show the lighting device, FIG. 7 shows the emission spectrum of the light emitting element, and FIGS. 8 to 11 show the evaluation results of light. In each drawing, the wiring connection relationship using lead wires or the like is omitted. In addition, the same code | symbol is attached | subjected to the same part and the overlapping description is abbreviate | omitted.

  The illuminating device of this embodiment is for a general house that is used by being attached to a hanging sealing body as a wiring device installed on the device mounting surface, and has a plurality of light emitting elements mounted on a substrate. The room is illuminated by light emitted from the section.

  The lighting device includes a device main body 1, a light source unit 2, a lighting device 3, a center member 4, and an attachment unit 5. Furthermore, the lighting device includes an optical sensor 6, a shade 7, a cover member 8, an indirect light source unit 9, and an auxiliary component unit 10. Moreover, the adapter A (refer FIG. 5) and infrared remote control transmitter Rc which are electrically and mechanically connected to the hooking sealing body Cb installed in the ceiling surface C as an apparatus attachment surface are provided. Such an illuminating device is formed in a round and circular appearance, and has a front side as a light irradiation surface and a back side as a mounting surface to the ceiling surface C. These components will be described sequentially.

  As shown in FIGS. 2 to 5, the apparatus main body 1 is a chassis having thermal conductivity formed in a circular shape from a flat plate of a metal material such as a cold-rolled steel plate, and a mounting portion described later at a substantially central portion. A circular opening 11 in which 5 is disposed is formed. The opening 11 is formed in a shape that is substantially equal to the outer shape of the mounting portion 5 with a part of a circular shape protruding outward.

  On the outer peripheral side of the opening 11, a projecting portion 12 having a quadrangular shape with a corner portion having an R shape and projecting to the back side is formed. Further, on the outer peripheral side of the apparatus main body 1, a circular annular protruding portion 13 that protrudes on the back side, in other words, forms a concave portion on the front side, is formed.

  In the recess formed by the protruding portion 13, a shade receiving bracket 75 to which the shade 7 is detachably attached is disposed. These protrusions 12 and 13 mainly function as attachment portions of members attached to the chassis, and also have a function of reinforcing the strength of the chassis and a function of increasing the heat radiation area.

  The apparatus main body 1 corresponds to a chassis in this embodiment, but may be referred to as a case, a reflector, or a base. In general, it means a member or a part where the light source unit 2 is directly or indirectly arranged, and is not interpreted in a particularly limited manner.

  As shown in FIGS. 2, 3, and 5, the light source unit 2 includes a substrate 21 and a plurality of light emitting elements 22 mounted on the substrate 21. In addition, illustration of the light emitting element 22 is abbreviate | omitted in FIG. The substrate 21 is disposed so that four substantially arc-shaped substrates 21 having a predetermined width dimension are connected to each other, and is formed in a substantially circle shape as a whole. That is, the substrate 21 formed in a substantially circle shape as a whole is composed of four divided substrates 21.

  By using the substrate 21 thus divided, it is possible to suppress the deformation of the substrate 21 by absorbing thermal contraction at the divided portion of the substrate 21. In addition, although it is preferable to use the board | substrate 21 divided | segmented into plurality, you may make it use the board | substrate of 1 sheet integrally formed in the substantially circle shape.

  The board | substrate 21 consists of a flat plate of the glass epoxy resin (FR-4) which is an insulating material, and the wiring pattern is formed with the copper foil on the surface side. The light emitting element 22 is electrically connected to this wiring pattern. Further, a daylight color resist layer acting as a reflective layer is provided on the wiring pattern, that is, on the surface of the substrate 21.

  The material of the substrate 21 can be a ceramic material or a synthetic resin material when an insulating material is used. Furthermore, when it is made of metal, a metal base substrate in which an insulating layer is laminated on one surface of a base plate having good thermal conductivity such as aluminum and excellent heat dissipation can be applied.

  The light emitting element 22 is an LED, which is a surface mount type LED package. A plurality of LED packages are mounted in a plurality of rows along the circumferential direction of the circle-shaped substrate 21, in the present embodiment, in three rows on the circumference of substantially concentric circles having different radii. That is, it is mounted over the inner circumferential row, the outer circumferential row, and an intermediate row between the inner circumferential row and the outer circumferential row.

  The LED package is roughly composed of an LED chip disposed in a cavity formed of ceramics or synthetic resin, and a translucent resin for molding such as epoxy resin or silicone resin that seals the LED chip. It is configured.

  The LED packages mounted on the inner and outer rows are light bulb colors (L) and daylight (D), which are on the circumference. They are arranged alternately at substantially equal intervals. The LED chip is an LED chip that emits blue light. In the translucent resin, a phosphor is mixed, and in order to be able to emit daylight color light of the light bulb color (L) and daylight color (D), it is mainly complementary to the blue light. Yellow phosphors that emit yellow light and red phosphors are used to supplement reddish components.

  As the LED packages mounted in the middle row, those that emit light in red (R), green (G), and blue (B) are used. Accordingly, the LED chips are LED chips that emit red, green, and blue light, respectively, and these LED chips are sealed with a translucent resin for molding.

  The LED packages that emit light in red (R), green (G), and blue (B) mounted in the middle row are sequentially red, red (R), green (G), and blue (B) in a substantially circular manner. Are arranged at regular intervals.

  More specifically, the LED packages emitting red (R), green (G), and blue (B) having different emission colors are substantially concentric circles having slightly different radial dimensions for each emission color, and are arranged in the circumferential direction. It is implemented by shifting the position.

  As such a light emitting element 22, an element having an emission spectrum characteristic as shown in FIG. 7 is used. FIG. 7 is a graph showing an emission spectrum, where the horizontal axis indicates the wavelength (nm) and the vertical axis indicates the specific energy (%).

  As shown in the figure, specifically, the light emitting element 22 that emits red (R) light has a peak wavelength of 620 nm to 640 nm, a full width at half maximum of 10 nm to 30 nm, and green (G). The light emitting element 22 that emits light has a peak wavelength of 510 nm to 530 nm and a full width at half maximum of 40 nm to 60 nm. The light emitting element 22 that emits blue (B) light has a peak wavelength of light. Those having a wavelength of 440 nm to 470 nm and a full width at half maximum of 10 nm to 30 nm are used.

  The light emitting element 22 that emits light of the light bulb color (L) has a peak wavelength of fluorescence derived from the phosphor of 550 nm to 650 nm and a full width at half maximum of 100 nm to 200 nm, and emits light of daylight color (D). The light emitting element 22 that emits light has a peak wavelength of fluorescence derived from the phosphor of 500 nm to 600 nm and a full width at half maximum of 100 nm to 200 nm.

  Here, in the case of the light emitting element 22 that emits light of light bulb color (L), blue light having a peak wavelength of 440 nm to 470 nm and a full width at half maximum of 10 nm to 30 nm is emitted from an LED chip that emits blue light. Fluorescence is emitted from the phosphor excited by the blue light. These lights are mixed and light bulb color (L) light is emitted.

  In the case of the light emitting element 22 that emits daylight color (D) light, similarly, blue light having a peak wavelength of 440 nm to 470 nm and a full width at half maximum of 10 nm to 30 nm is emitted from an LED chip that emits blue light. Fluorescence is emitted from the phosphor excited by blue light. These lights having a peak wavelength of 500 nm to 600 nm and a full width at half maximum of 100 nm to 200 nm are mixed and light of daylight color (D) is emitted.

  The arrangement of red (R), green (G), and blue (B) in the LED package is not specified and may be in any order. For example, the arrangement is in the order of green (G), red (R), and blue (B). May be. Further, adjacent LED packages are preferably arranged with different emission colors, but are not particularly limited. As an example, it is possible to continuously arrange two same colors such as red (R), red (R), green (G), green (G), blue (B), and blue (B). is there.

  In this way, a plurality of light emitting elements 22 that emit light in the light bulb color (L) and the daylight color (D) are arranged in a line on the circumference of substantially concentric circles having different radii, and the circumference of the circle having the same center as the circle is arranged. A plurality of light emitting elements that emit light in red (R), green (G), and blue (B) in a row between the light emitting elements 22 that emit light in the light bulb color (L) and daylight color (D). An element 22 is provided.

  Accordingly, a plurality of light emitting elements 22 having different emission colors having the emission spectrum characteristics, that is, light emission emitting light in the light bulb color (L), daylight color (D), red (R), green (G), and blue (B). Since the element 22 is disposed, the range of light colors that can be expressed by mixing these elements is wide, and the light color can be appropriately adjusted by adjusting the light output of the light emitting element 22. It becomes.

  In addition, LED may be made to mount an LED chip directly on the board | substrate 21, and you may make it mount a bullet-type LED, and a mounting system and a format are not exceptionally limited.

  In the light source unit 2 configured as described above, the substrate 21 is located on the front side of the apparatus main body 1 and around the opening 11 as shown in FIGS. The surface is disposed so as to face the front side, that is, the lower irradiation direction. Further, the substrate 21 is attached by a fixing means such as a screw so that the back surface side of the substrate 21 is in close contact with the inner surface side of the apparatus main body 1. Therefore, the substrate 21 is thermally coupled to the apparatus main body 1, and heat from the substrate 21 is conducted from the back side to the apparatus main body 1 to be radiated.

  As shown in FIGS. 2 and 5, a light source unit cover 25 is disposed on the front side of the light source unit 2. The light source cover 25 is made of, for example, a transparent synthetic resin having an insulating property such as polycarbonate or acrylic resin, and is integrally formed in a substantially circle shape along the arrangement of the light emitting elements 22, and includes the light emitting elements 22. Are arranged so as to cover the entire surface of the substrate 21.

  Therefore, the light emitted from the light emitting element 22 passes through the light source unit cover 25. Further, since the entire surface of the substrate 21 is covered, the charging unit is covered with the light source unit cover 25 to ensure insulation.

  As shown in FIG. 5, the lighting device 3 includes a circuit board and circuit components such as a control IC, a transformer, and a capacitor mounted on the circuit board. The circuit board is formed in a plate shape so as to surround the center portion, and circuit components are mounted on the surface side thereof.

  The circuit board is electrically connected to the adapter A side, and is connected to a commercial AC power source via the adapter A. Therefore, the lighting device 3 receives this AC power supply, generates a DC output, supplies the DC output to the light emitting element 22 via the lead wire, and controls the lighting of the light emitting element 22.

  Such a lighting device 3 is attached to and covered with the lighting device cover 35 and arranged on the back side of the device body 1 as shown in FIG. In this case, the circuit board is attached with the circuit components facing the front side (the lower side in the drawing).

  The lighting device cover 35 is formed in a substantially rectangular short cylinder shape by a metal material such as a cold rolled steel plate, and the side wall 35a is inclined so as to expand toward the front surface side. An opening 35c is formed at the center.

  As shown in FIGS. 4 and 5, the lighting device cover 35 is mounted with a front-side flange mounted on the protruding portion 12 of the chassis and screwed.

  An elastic member 36 is attached to the back side of the lighting device cover 35. The elastic member 36 is attached in the vicinity of the attachment position of each of the plurality of indirect light source units 9. The elastic member 36 is a member disposed so as to be interposed with elastic deformation between the lighting device and the ceiling surface C in a state where the lighting device is attached to the ceiling surface C as the device mounting surface. It acts to securely hold the ceiling surface C.

  As shown in FIGS. 2, 3 and 5, the center member 4 is made of a synthetic resin material such as PBT resin, is formed in a substantially short cylindrical shape, and is hooked at the center to face the sealing body Cb. An opening 41 is provided. An annular space 42 is formed around the opening 41, and the optical sensor 6 described later is disposed in the space 42. Further, a light receiving window 43 that faces the light receiving portion of the optical sensor 6 is formed on the front wall of the center member 4.

  The center member 4 configured in this manner has a back side flange as shown mainly in FIG.

The screw is attached to the chassis via the light source cover 25 by screwing. The center member 4 can be directly or indirectly attached to the chassis, and its specific attachment configuration is not limited.

  The attachment portion 5 is an adapter guide, a member through which the adapter A is inserted and engaged, and a member for attaching the lighting device to the ceiling surface C. As shown in FIG. 5, the adapter guide is formed in a substantially cylindrical shape, and an engagement port 51 through which the adapter A is inserted and engaged is provided at the center. The adapter guide is disposed corresponding to the opening 11 formed in the central portion of the main body 1.

  Note that the attachment portion 5 is not necessarily a member referred to as an adapter guide or the like. For example, it may be an opening formed in the apparatus main body 1 or the like, and in essence, it means a member or part that is opposed to the hooking sealing body Cb as a wiring device and to which the adapter A is engaged.

  As shown in FIG. 5, the optical sensor 6 is mounted on a substrate, and is disposed and attached in the space 42 of the center member 4 so that the light receiving portion thereof faces the light receiving window 43. The optical sensor 6 is an illuminance sensor, and includes a sensor element such as a photodiode, and operates to detect ambient brightness and output a detection signal. Thereby, when the surroundings are bright, the light source unit 2, that is, the light emitting element 22 is controlled to be dimmed (dimmed) and lit.

  The shade 7 is formed in a substantially circular shape from a material having translucency such as acrylic resin, and having a diffusibility exhibiting a milky daylight color, and a circular opening 71 is formed in the central portion. A shade decorative frame 7a is attached to the outer periphery of the shade 7, and the shade decorative frame 7a is formed of a transparent material made of acrylic resin or the like.

  The shade 7 is detachably attached to the outer peripheral edge of the main body 1 so as to cover the front side of the main body 1 including the light source section 2. Specifically, by rotating the shade 7, the shade mounting bracket 74 provided on the shade 7 is engaged with the shade receiving bracket 75 provided in the recess formed by the protruding portion 13 of the apparatus body 1. Can be installed.

  Further, when removing the shade 7, it can be removed by rotating the shade 7 in the direction opposite to that at the time of attachment and releasing the engagement between the shade attachment fitting 74 and the shade receiving fitting 75.

  The cover member 8 is formed in a circular shape from a material such as a transparent acrylic resin. The cover member 8 corresponds to the opening 71 of the shade 7, is attached to the front wall of the center member 4, and is disposed so as to cover and close the opening 41 of the center member 4. The cover member 8 is formed with a transmission portion 81 that faces the light receiving window 43 of the optical sensor 6.

  The indirect light source unit 9 is disposed on the back side of the apparatus main body 1 and mainly has a function of illuminating the ceiling surface brightly. As shown in FIGS. 4 and 5, a plurality of indirect light source units 9 are disposed around the mounting unit 5, and a substrate 91 and a plurality of light emitting elements 92 mounted on the substrate 91 are disposed. And.

  The substrate 91 is formed in a substantially rectangular flat plate, and the light emitting elements 92 are mounted in a line along the longitudinal direction of the substrate 91.

  Substrates 91 on which the light emitting elements 92 are mounted are attached to four locations on the side wall 35 a of the lighting device cover 35. In this case, the lighting device cover 35 is formed in a substantially square shape, and the substrate 91 is attached to the linear flat surface of the side wall 35a, so that the attachment is stably performed.

  Further, since the side wall 35a that forms the mounting portion of the substrate 91 is formed in an inclined shape that expands toward the front side, the substrate 91 is directed obliquely upward, that is, in the ceiling surface direction, and the light emitting element The light emitted from 92 is effectively irradiated toward the ceiling surface direction.

  Furthermore, each indirect light source unit 9 is covered with a translucent cover 93 formed in an inclined shape such that its cross section expands toward the back side.

  The light emitting element 92 is an LED, like the light source unit 2, and is a surface mount type LED package, and the light emitting color is a light bulb color (L). The light emitting element 92 has the same emission spectrum characteristics as the light emitting element 22 that emits light of the light bulb color (L) of the light source unit 2. The light emitting element 92 is connected to the lighting device 3 and is controlled to be turned on.

  As shown in FIGS. 2, 3 and 5, the auxiliary component unit 10 includes a unit substrate 101 and a plurality of electrical auxiliary components mounted on the substrate 101. The electrical auxiliary components in this embodiment are an infrared remote control signal receiving unit 102, a night light emitting element 103, a channel setting switch 104, and the like. The auxiliary component unit 10 is disposed on the front side of the apparatus main body 1 and inside the light source unit 2.

  As shown in FIG. 5, the adapter A is electrically and mechanically connected to a hooking sealing body Cb installed on the ceiling surface C by a hooking blade provided on the upper surface side, and has a substantially cylindrical shape. A pair of locking portions A1 are provided on both sides of the peripheral wall so as to always protrude to the outer peripheral side by a built-in spring. The locking portion A1 is immersed by operating a lever provided on the lower surface side. Further, a power cord (not shown) connected to the lighting device 3 is led out from the adapter A, and is connected to the lighting device 3 via a connector.

  The infrared remote control transmitter Rc transmits, for example, a specific coded infrared remote control signal in the form of a pulse having a frequency of 38 kHz. For example, a mode switching button, an all-light button, a dimming button, a nightlight button, An off button is provided. By operating the remote control transmitter Rc toward the auxiliary component unit 10, that is, the infrared remote control signal receiving unit 102, the illumination state of the light source unit 2 and the indirect light source unit 9 can be controlled.

  Next, a schematic block configuration of the illumination device according to the present embodiment will be described with reference to FIG. As shown in the figure, the lighting device 3 is connected to a commercial AC power supply AC, the light source unit 2 and the indirect light source unit 9 are connected to the lighting device 3, and a control unit 31.

  The lighting device 3 functions as a DC power source, and receives a commercial AC power source AC and generates a DC output. As described above, the light source 2 is mounted on the substrate 21 and connected to the light bulb color (L), daylight color (D), red (R), green (G), and blue (B). The light emitting elements 22 having different colors are provided. The indirect light source unit 9 includes a light emitting element 92 that emits light of a light bulb color (L).

  The control unit 31 includes a setting information input / output unit 32 and a dimming control unit 33 and a storage unit 34 connected to the setting information input / output unit 32. The setting information input / output unit 32 includes an infrared remote controller. A signal receiving unit 102 is connected. The storage unit 34 is provided with a mode storage unit 341.

  The dimming control means 33 is provided with a PWM control circuit 331 and a switching control circuit 332 connected to the PWM control circuit 331. The PWM control circuit 331 and the switching control circuit 332 have five light emission colors which emit light of the light bulb color (L), daylight color (D), red (R), green (G), and blue (B) of the light source unit 2. The six light emitting elements 22 and the light emitting elements 92 that emit light of the light bulb color (L) of the indirect light source unit 9 are provided. Thereby, while being able to control the light source part 2 and the indirect light source part 9 independently, the light control for every luminescent color is attained. Therefore, for the light source unit 2, the light output for each emission color is varied by adjusting the dimming ratio for each emission color, and the light bulb color (L), daylight color (D), red (R), green (G), Blue (B) emission color can be mixed to express a desired emission color.

  In such a configuration, in order to produce a light space suitable for a living scene, a desired mode can be selected and switched from among a plurality of lighting modes, that is, six lighting modes. Specifically, in the light emitting elements 22 and 92, six mode setting information (lighting pattern information) in which the light output for each emission color is adjusted are stored in the mode storage unit 341. This mode can be selected by the infrared remote controller transmitter Rc to reproduce the lighting pattern.

  For example, six modes of “Azayaka”, “Study”, “Good night”, “Relax”, “Theater”, and “Healing” are set.

  In the “Azayaka” mode, the light emission color (L), daylight color (D), red color (R), green color (G), and blue color (B) are mixed and the average color rendering evaluation Ra88 and color reproducibility are high. It expresses daylight-colored light that excels in nature, and shows the table and colors vividly and beautifully.

  The “study” mode is a daylight white light with a high correlated color temperature (5100K) that is generally easy to identify characters, and is effective for concentration by adding green (G) and blue (B) light components. It creates light.

  “Good night” mode represents green (G) light. Green (G) light is more difficult to transmit through the eyelids than other light colors, so it allows you to work a little at night while preventing people sleeping next to you from being dazzled. is there.

  The “relaxation” mode is a combination of the downward light of the light bulb color (L) by the light source unit 2 and the upward light of the light bulb color (L) by the indirect light source unit 9 to make the entire space of the light bulb color (L). Illuminated with soft light, it creates a relaxing and relaxing space.

  The “theater” mode is illumination by only the upward light of the light bulb color (L) by the indirect light source unit 9. It can illuminate the ceiling surface, create a cinematic presence, and create a light space for enjoying the home theater.

  The “Healing” mode expresses marine blue light that is associated with water and light, and creates a relaxing space for relaxation and healing.

  Specifically, in the case of the “bright” mode, the lighting pattern is 2 to 32% of red (R) light, 5 to 62% of green (G) light, and blue (B) as a light mixture ratio (light flux ratio). The light is 0.5 to 6%, the light of the light bulb color (L) and the light of daylight color (D) is 0 to 92.5%, and the breakdown is 40 light of the light bulb color (L). ˜50%, daylight color (D) light is set to a ratio of 50 to 60%.

  In the “study” mode, the lighting pattern has a light mixture ratio (light flux ratio) of red (R) light of 0%, green (G) light of 8 to 43%, blue (B) light of 2 to 13%, The combined light of the light bulb color (L) and the daylight color (D) is 44% to 90%, and the breakdown is 30-40% of the light bulb color (L) light and the daylight color (D) light. Is set to 60 to 70%.

  In the “healing” mode, the lighting pattern has a light mixture ratio (light flux ratio) of 0% for red (R) light, 90 to 95% for green (G) light, and 5 to 10 for blue (B) light. %, Light bulb color (L) light and daylight color (D) light are set to a ratio of 0%.

  When reproducing the mode set in this way, the infrared remote control transmitter Rc is operated to select a specific mode. When this mode selection signal is received by the infrared remote control signal receiving unit 102, the signal is transmitted to the setting information input / output unit 32. The setting information input / output unit 32 reads the mode setting information (lighting pattern information) selected from the mode storage unit 341 and transmits it to the dimming control means 33.

  The PWM control circuit 331 in the dimming control means 33 generates a PWM control signal based on the mode setting information and sends it to the switching control circuit 332. In the switching control circuit 332, the DC output from the lighting device 3 is PWM-controlled based on the PWM control signal, and the light source unit 6, that is, the light bulb color (L), the daylight color (D), the red color (R), and the green color (G). , Blue (B) light-emitting elements 22 of the respective colors and the light-emitting element 92 of the light bulb color (L) of the indirect light source 9. As a result, the light emitting elements 22 and 92 of each color are controlled for each light emission color at a light control ratio according to the mode setting information, and light is emitted at a predetermined light mixture ratio, so that the light emission color mixed as a whole is expressed. .

  Next, the attachment state to the ceiling surface C of an illuminating device is demonstrated with reference to FIG. First, the adapter A is electrically and mechanically connected to the hanging sealing body Cb installed on the ceiling surface C in advance. With the cover member 8 of the illuminating device removed, the apparatus main body 1 is held until the engaging portion 51 of the adapter A is securely engaged with the engaging port 51 of the adapter guide while the engaging port 51 of the adapter guide is aligned with the adapter A. The mounting operation is performed by manually pushing up from the lower side against the elastic force of the elastic member 36.

  Next, the cover member 8 is attached, and the cover member 8 is closed and covered with the opening 41 in the center portion of the center member 4 facing the hooking sealing body Cb.

  Further, when removing the lighting device, the cover member 8 is removed, and the lever provided on the adapter A is operated through the opening 41 of the center member 4 to disengage the engaging portion A1 of the adapter A to remove it. be able to.

  Next, the results of various evaluations in designing such an illuminating device will be described with reference to FIGS.

  (Evaluation Result 1) As shown in FIG. 8, the color rendering properties are evaluated. FIG. 8 shows an a * b * chromaticity coordinate diagram, in which JIS color rendering evaluation test colors No. 1 to No. 8 are “light” mode light, light bulb color (L), and daylight color (D) light emitting elements. It compares how it looks when illuminated with light that is only lit.

  Evaluation test color No. 1-No. When the chromaticity points when illuminating 8 with a light source are connected by a line segment, an octagon is formed, but the more the octagon spreads outward, the more vivid it will look. Comparing the octagon formed by the light of the “Azakaya” mode light and the light emitting element of the light bulb color (L) and the daylight color (D), the light of the “Azakaya” mode has the light bulb color and daylight color. It can be seen that the octagon spreads outward than the light of only the light emitting element.

  Therefore, it can be confirmed that the illumination with the light in the “bright” mode looks more vivid than the illumination with only the light emitting elements of the light bulb color (L) and the daylight color (D).

  The light in the “bright” mode emits light from the light emitting elements of red (R), green (G), and blue (B) in contrast to light emitted from the light emitting elements of the light bulb color (L) and daylight color (D). By mixing colors of about 7% or more, it is designed to make food look more vivid than when only light emitted from light-emitting elements of light bulb color (L) and daylight color (D).

  (Evaluation Result 2) As shown in FIGS. 9 (a), 9 (b) and 9 (c), the evaluation about the consciousness when solving the calculation problem is shown. FIG. 9A shows the number of missed responses when the subject solves the calculation problem. FIG. 9B shows whether or not the work can be performed with a clear consciousness when solving the calculation problem, and FIG. 9C shows whether or not the work can be concentrated.

  Here, the condition 1 is light in which only light-emitting elements of the light bulb color (L) and daylight color (D) are turned on for the first time, and light-emitting elements of light bulb color (L) and daylight color (D) are also turned on in the second time. When illuminating with the emitted light, the condition 2 is a case where only the light emitting element of the light bulb color (L) and the daylight color (D) is turned on the first time, and the second time is illuminated with the light of “study” mode.

  In FIG. 9A, the horizontal axis indicates the number of times, and the vertical axis indicates the average number of missed responses.

  As a result, it can be seen that when illuminated with light in the “study” mode, the number of missed responses is reduced and works effectively.

  Similarly, it can be seen that the clear consciousness shown in FIGS. 9B and 9C and whether or not the work can be concentrated are improved when illuminated with the light in the “study” mode.

  Regarding the readability of the characters, the subjects who evaluated that the characters were easy to read were 20% when the light-emitting elements of the light bulb color (L) and daylight color (D) were turned on, and 60% when the light was in “Study” mode. there were. The light of “study” mode is mixed with light of light bulb color (L), daylight color (D), green (G) and blue (B) more than 10%, and brightness is light bulb color (L) And the daylight color (D) light-emitting elements are realized by setting the light output to be equivalent to that when the light-emitting elements are all turned on.

  (Evaluation Result 3) FIG. 10 shows the result of evaluation in which six light colors of red, yellow, green, blue-green, blue, and purple are presented to the subject and ranked up to the third place in order of high relaxation effect. ing. In the figure, the horizontal axis indicates the average value of the points, and the vertical axis indicates each light color.

  It shows the average value of eight subjects when the light color selected as the first place is converted into 3 points, 2nd place is 2 points, 3rd place is 1 point, and the others are 0 points. As a result, blue-green has the highest relaxing effect.

  Therefore, in the “Healing” mode, 95% of green (G) light and 5% of blue (B) light are mixed as blue-green light, and the light emitting elements of the light bulb color (L) and daylight color (D) are all lit. This is realized by setting the light output to about 0.038 times that when the light is turned on.

  (Evaluation result 4) FIG. 11 shows the subject watching a video while the light emitting element 22 of the light bulb color (L) in the light source unit 2 and the light emitting element 92 of the light bulb color (L) in the indirect light source unit 9 are lit. It shows the result of an evaluation that answered whether the lighting environment is suitable for watching TV.

  The light of the light bulb color (L) in the light source unit 2 and the light of the light bulb color (L) in the indirect light source unit 9 are turned on so as to have an equivalent light output.

  As a result, when the television color is viewed, the light-emitting element 92 of the light bulb color (L) is turned on by the indirect light of the light bulb color (L) in the indirect light source portion 9 rather than the direct light of the light bulb color (L) in the light source portion 2. It turns out that it is suitable for. This result is realized as a “theater” mode.

  When power is supplied to the lighting device 3 in a state where the lighting device is attached to the ceiling surface C, the light emitting elements 22 are energized through the substrate 21 in the light source unit 2, and each light emitting element 22 is lit. The light emitted from the light emitting element 22 to the front side is transmitted through the light source cover 25 and is expanded by the shade 7.

  At the same time, when the indirect light source unit 9 is energized, each light emitting element 92 is turned on, and the light emitted obliquely upward from the light emitting element 92 is transmitted through the translucent cover 93 and the adapter guide 5 The ceiling surface is mainly irradiated so as to be emitted from the surroundings. Therefore, the ceiling surface becomes bright and the feeling of brightness in the space can be improved.

  In addition, by reproducing a plurality of modes, it is possible to produce an appropriate light space according to the life scene.

  The heat generated from the light emitting element 22 is effectively conducted to the apparatus main body 1 and is dissipated over a wide area because the back side of the substrate 21 is thermally coupled to the apparatus main body 1.

  As described above, according to the present embodiment, light emission of five colors that emits light bulb color (L), daylight color (D), red (R), green (G), and blue (B) having the characteristics of the emission spectrum. Light emitting elements 22 having different colors are used, and the light output of these light emitting elements 22 has a plurality of modes in which the light output is adjusted, and the serial number.

Therefore, it is possible to provide a lighting device that can widen the range of light colors that can be expressed and can produce an appropriate light space according to the life scene.

  In addition, this invention is not limited to the structure of the said embodiment, A various deformation | transformation is possible in the range which does not deviate from the summary of invention. Moreover, the said embodiment is shown as an example and is not intending limiting the range of invention.

DESCRIPTION OF SYMBOLS 1 ... Apparatus main body (chassis), 2 ... Light source part,
3 ... lighting device, 4 ... center member,
5 ... Mounting part (adapter guide), 6 ... Optical sensor,
7 ... sade, 8 ... cover member,
9 ... Indirect light source unit, 10 ... Auxiliary component unit,
21 ... substrate, 22 ... light emitting element (LED),
25 ... light source cover, 31 ... control means,
32 ... Setting information input unit, 33 ... Dimming control means,
34 ... Storage means, 92 ... Light emitting element of indirect light source,
102: Infrared remote control signal receiving unit, 341: Mode storage unit,
A ... Adapter, C ... Device mounting surface (ceiling surface), Cb ... Wiring device (hook ceiling body), Rc ... Infrared remote control transmitter

Claims (1)

A white light source that emits light bulbs and daylight;
A primary color light source emitting primary color light;
A lighting device comprising:
The illuminating device can be controlled to turn on only the white light source and includes a dedicated mode for turning on the white light source and the primary color light source.
The illumination apparatus according to claim 1, wherein the illumination light in the dedicated mode is set to have higher color rendering than when only the white light source is turned on.

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