JP6519891B2 - lighting equipment - Google Patents

Description

  Embodiments of the present invention relate to a luminaire.

  For example, development of a lighting fixture using a light emitting element such as a light emitting diode (LED) as a light source has been advanced. As a lighting fixture which uses a light emitting diode as a light source, the ceiling light attached to the ceiling surface etc. of a house etc. is mentioned, for example. In such a luminaire, it is desired not only to illuminate the surroundings brightly but also to create an appropriate light space adapted to the life scene as the lifestyle diversifies. For example, it is desirable to make the light uniform on the light emitting surface of the luminaire.

JP 2012-252899 A

  An embodiment of the present invention provides a luminaire capable of achieving uniform light on a light emitting surface.

According to an embodiment, there is provided a lighting fixture comprising a fixture body, a substrate, a plurality of light emitting elements, a light distribution control unit, and a cover. The substrate is disposed on the front side of the device body. The plurality of light emitting elements are mounted on the substrate and disposed on the substrate. The light distribution control unit includes a lens unit that covers the plurality of light emitting elements and controls light distribution of the plurality of light emitting elements, and a flat portion facing the substrate between the lens units, and the light is diffused in the flat portion Processed and covered from the front of the substrate. The cover has a diffusing property that covers the front side of the light distribution control unit. The plurality of light emitting elements include a white light source and a chromatic color light source. A diffusion process is performed on the lens unit that controls the light distribution of the chromatic color light source.

  According to an embodiment of the present invention, a lighting fixture capable of achieving uniform light on a light emitting surface is provided.

Fig.1 (a) and FIG.1 (b) are typical perspective views showing the lighting fixture concerning embodiment. It is a typical exploded view showing a lighting fixture concerning an embodiment. Drawing 3 (a) and Drawing 3 (b) are typical top views showing the lighting fixture concerning an embodiment. Drawing 4 (a) and Drawing 4 (b) are typical sectional views showing a lighting fixture concerning an embodiment. Drawing 5 (a) and Drawing 5 (b) are typical sectional views showing a lighting fixture concerning an embodiment. FIG. 6A to FIG. 6C are graphs showing the relative spectral distribution of light emitted from the light emitting element of the embodiment. It is a block diagram showing the principal part composition of the lighting fixture concerning an embodiment. FIG. 8A and FIG. 8B are schematic plan views showing the remote control transmitter of the embodiment. It is a graph showing the relative spectral distribution of the light which a light emitting element emits in "night-rest assist" mode. It is a table which illustrates the relationship between the light mixing ratio and the degree of melatonin suppression. It is a graph which illustrates the relationship between the light control ratio of the light emitting element which emits the light of bulb color, and the melatonin suppression relative value. It is xy chromaticity diagram explaining the example of the control which the control part of embodiment performs in "good night assistance" mode. Drawing 13 (a) and Drawing 13 (b) are relative spectral distribution explaining the other example of the control which the control part of an embodiment performs in "rest of night assist" mode. Drawing 14 (a) and Drawing 14 (b) are xy chromaticity diagrams explaining an example of control which a control part of an embodiment performs. It is a L ^* a ^* b ^* colorimetric system which demonstrates the other example of the control which the control part of embodiment performs. It is a flowchart figure explaining the other example of the control which the control part of embodiment performs. It is a flowchart figure explaining the other example of the control which the control part of embodiment performs. It is a flowchart figure explaining the other example of the control which the control part of embodiment performs. It is a flowchart figure explaining the other example of the control which the control part of embodiment performs. It is a flowchart figure explaining the other example of the control which the control part of embodiment performs.

  Hereinafter, embodiments will be described with reference to the drawings. The same parts in the drawings are denoted by the same reference numerals, and the detailed description thereof is appropriately omitted, and different parts will be described. The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the ratio of sizes between parts, and the like are not necessarily the same as the actual ones. In addition, even in the case of representing the same portion, the dimensions and ratios may be different from one another depending on the drawings.

Fig.1 (a) and FIG.1 (b) are typical perspective views showing the lighting fixture concerning embodiment.
FIG. 2 is a schematic exploded view showing the lighting apparatus according to the embodiment.
Drawing 3 (a) and Drawing 3 (b) are typical top views showing the lighting fixture concerning an embodiment.
Fig.1 (a) is a typical perspective view showing the light emission surface side of the lighting fixture concerning embodiment. FIG. 1B is a schematic perspective view showing the side opposite to the light emitting surface of the lighting apparatus according to the embodiment. Fig.3 (a) is a schematic plan view showing the light emission surface side of the lighting fixture concerning embodiment. FIG.3 (b) is the schematic enlarged view which expanded and looked at area | region A1 represented to Fig.3 (a).

  The luminaire according to the embodiment is for general household use which is attached to a hook sealing body as a wiring instrument installed on an instrument mounting surface. The lighting fixture according to the embodiment performs indoor lighting with light emitted from a light source unit having a plurality of light emitting elements mounted on a substrate.

As shown in FIGS. 1A to 3B, the lighting fixture 100 according to the embodiment includes a power supply unit 110, a fixture body 120, a light source unit 130, a light distribution control unit 140, and a cover 150. And.
The cover 150 is, for example, a milky white acrylic resin molded body, and has light transparency. The lower surface 150a of the cover 150 forms a light emitting surface.

  Although the external shape of the lighting fixture 100 represented to FIG. 1 (a)-FIG.3 (b) is circular, it is not necessarily limited to this. For example, the outer shape of the lighting fixture 100 may be oval or square.

  The power supply unit 110 has a chassis formed of a flat plate of a metal material such as a cold-rolled steel plate. The chassis of the power supply unit 110 is combined in a ring shape. Inside the chassis of the power supply unit 110, a circuit component 116 including a control unit 115 is provided (see FIG. 2). As shown in FIG. 1B, the power supply unit 110 has a fitting portion 111 at the center of the upper surface 110a. The fitting portion 111 fits, for example, a hooking sealing body as a connecting device (wiring device) provided on a ceiling of a house, and fixes the device body 120 to the ceiling. Attached to the fitting portion 111 is an adapter guide 113 for guiding the hooking sealing body.

  In the specification of the present application, for convenience of explanation, the side of the cover 150 is referred to as “downward” when viewed from the power supply unit 110, and the side of the power supply 110 is referred to as “upper” when viewed from the cover 150. This is also true for other components.

  The tool body 120 is a chassis formed by molding a flat plate of a metal material such as a cold-rolled steel plate, for example. A hole 121 for passing the adapter guide 113 is formed in a substantially central portion of the instrument body 120.

  The light source unit 130 includes a substrate 131 and a plurality of light emitting elements 133, and is provided so as to be separable from the power supply unit 110 through the connection unit. The light emitting element 133 is provided on the lower surface 131 a of the substrate 131. The substrate 131 has a structure in which two substantially arc-shaped substrates having a predetermined width dimension are joined together, and is formed in a substantially annular shape as a whole. That is, the substrate 131 formed in a substantially annular shape as a whole has two divided substrates. The plurality of divided substrates 131 are electrically connected by a connector (electrical connection portion) CN via a wire 135 or the like inside the substrate 131. The substrate 131 is fixed to the lower surface 120 a of the tool body 120. The substrate 131 may have four divided substrates.

  By using the divided substrate, thermal contraction can be absorbed by the divided portion of the substrate 131, and deformation of the substrate 131 can be suppressed. In addition, although it is preferable to use the board | substrate divided | segmented into plurality, one board | substrate integrally formed in substantially annular shape may be used. Furthermore, on the inner peripheral side of the specific substrate 131, a power supply unit 137 is provided. Specifically, the power supply unit 137 is a connector CN. An output line W electrically connected to the lighting device is connected to the power supply unit 137, and power is supplied to the plurality of light emitting elements 133 through the wiring pattern of the substrate 131.

  On the lower surface 131 a of the substrate 131, a member that reflects the light emitted from the light emitting element 133 is applied. For example, on the lower surface 131a of the substrate 131, a resin in which titanium oxide or the like is dispersed is applied. By applying the reflective member to the lower surface 131 a of the substrate 131, it is possible to prevent the decrease in luminance at the central portion of the tool body 120.

  The substrate 131 includes, for example, an insulating substrate such as glass epoxy resin, and a wiring formed using a copper foil. The reflective member is applied to the lower surface 131 a of the substrate 131 except for the portion where the light emitting element 133 is disposed. That is, the substrate 131 has a wiring hidden by the reflective member, and electrically connects the plurality of light emitting elements 133.

  The light emitting element 133 is an LED (Light Emitting Diode). The light emitting element 133 is a surface mount type LED package. As shown in FIGS. 3A and 3B, the LED package is mounted along the circumferential direction of a plurality of (two in the example of FIG. 3A) circular substrates 131. . Further, the LED packages are mounted over a plurality of rows (three rows in the example of FIG. 3A) on the circumferences of substantially concentric circles having different radii. That is, in the LED package, the inner row (first row), the outer row (second row), and the middle row between the inner row and the outer row (third row) ) Is implemented.

  The LED package generally includes an LED chip disposed in a cavity formed of a ceramic or a synthetic resin, and a translucent resin for molding such as an epoxy resin or silicone resin for sealing the LED chip. Have.

  In the LED package (first white light source) mounted in the inner circumferential side row, the light emitting element 133L (first light emitting element) whose light emission color is a light bulb color (L) and the light emission color is daylight color (D) The light emitting element 133D (second light emitting element) is used. The color temperature of daylight (D) light is higher than the color temperature of light of bulb color (L). That is, the light emitting element 133D emits light of a color temperature higher than the color temperature of the light of the light bulb color (L). The light emitting elements 133L and the light emitting elements 133D are alternately arranged at substantially equal intervals on the circumference. The LED chip is an LED chip that emits blue light. A fluorescent substance is mixed in the translucent resin. In order to be able to emit daylight light of a bulb color (L) and a daylight color (D), as a phosphor, a yellow phosphor or a yellow phosphor that emits a yellowish light having a complementary color to the blue light A red phosphor is used to compensate for the reddish component. The mounting form of the LED package (second white light source) of the outer peripheral side row is similar to the mounting form of the LED package of the inner peripheral side row.

  In the present specification, for convenience of explanation, at least one of the light emitting element 133L whose light emitting color is a light bulb color (L) and the light emitting element 133D whose light emitting color is a daylight color (D) is referred to as "white light source" or "main light source". . In other words, "white light source" and "main light source" refer to a light source having chromaticity coordinates within the domain of correlated color temperature.

  In the LED package mounted in the middle row, the light emitting element 133R (third light emitting element) of which the light emitting color is red (R) and the light emitting element 133G (fourth light emitting element) of which the light emitting color is green (G) And a light-emitting element 133B (fifth light-emitting element) whose emission color is blue (B). The LED chip of the light emitting element 133R is an LED chip that emits red light. The LED chip of the light emitting element 133G is an LED chip that emits green light. The LED chip of the light emitting element 133B is an LED chip that emits blue light. These LED chips are sealed by a translucent resin for molding.

  In the specification of the present application, for convenience of explanation, at least one of the light emitting element 133R emitting light of red (R), the light emitting element 133G emitting green (G), and the light emitting element 133B emitting blue (B) Is referred to as "chromatic light source" or "secondary light source". In other words, "chromatic light source" and "sub light source" refer to a light source that emits light within a narrow wavelength range as represented by single wavelength light or single wavelength light.

The light emitting element 133R, the light emitting element 133G, and the light emitting element 133B are sequentially arranged at substantially equal intervals with the light emitting element 133R, the light emitting element 133G, and the light emitting element 133B on a substantially circumference.
The details of the wavelength of the light emitted by each light emitting element and the details of the correlated color temperature of the light emitted by each light emitting element will be described later.

  The arrangement of the light emitting elements 133R, the light emitting elements 133G, and the light emitting elements 133B may not be specified, and may be random. For example, the light emitting elements 133G, the light emitting elements 133R, and the light emitting elements 133B may be arranged in this order. In addition, although it is preferable that adjacent light emitting elements emit light of different colors, the light emitting elements are not particularly limited. As an example, it is also possible to arrange two light emitting elements emitting light of the same color successively as the light emitting element 133R, the light emitting element 133R, the light emitting element 133G, the light emitting element 133G, the light emitting element 133B, and the light emitting element 133B. It is possible.

  According to the embodiment, a plurality of light emitting elements 133 having different emission colors, that is, light emitting elements 133L emitting light of light bulb color (L), light emitting elements 133D emitting light of daylight color (D), red (R) A light emitting element 133R that emits light, a light emitting element 133G that emits green (G) light, and a light emitting element 133B that emits blue (B) light are disposed. This makes it possible to widen the range of light colors that can be expressed by mixing the light of each color. In addition, by individually controlling the output of light emitted from each light emitting element, it is possible to appropriately adjust the color of light. In the present specification, for convenience of explanation, light in which light of each color is mixed at a predetermined ratio is referred to as “mixed light”.

  The light distribution control unit 140 controls light distribution of the light emitting element 133. The light distribution control unit 140 will be further described with reference to the drawings.

Drawing 4 (a) and Drawing 4 (b) are typical sectional views showing a lighting fixture concerning an embodiment.
Drawing 5 (a) and Drawing 5 (b) are typical sectional views showing a lighting fixture concerning an embodiment.
FIG. 4A is a schematic cross-sectional view of the cut surface A-A shown in FIG. FIG.4 (b) is typical sectional drawing in cut surface BB represented to Fig.3 (a). FIG. 5A is a schematic cross-sectional view of the cut surface C-C shown in FIG. FIG.5 (b) is typical sectional drawing in cut surface DD shown to Fig.3 (a).

  As illustrated in FIG. 4A, the light distribution control unit 140 is fixed to the device body 120 and covers the light emitting element 133 and the electrical connection portion and the power supply portion between the plurality of divided substrates 131. . The material of the light distribution control unit 140 includes, for example, a resin. The light distribution control unit 140 covers the entire light source unit (charging unit) 130. Therefore, the light distribution control unit 140 has a function of protecting the light source unit 130. A convex portion 145 corresponding to the electrical connection portion and the power supply portion of the substrate 131 is formed on the inner peripheral side of the light distribution control unit 140. The convex portion 145 is formed to have a dimension longer than the connector dimension in the circumferential direction which is the annular direction. That is, since the light distribution control unit 140 has a structure in which the light distribution control unit 140 is attached to and detached from the instrument main body 120, the light distribution control unit 140 does not interfere with the electrical connection portion CN and the electric wire 135 when the light distribution control unit 140 rotates. Has a projection 145 which is longer than the connector size.

  The light distribution control unit 140 has a lens unit 141. The lens portion 141 has a first portion 141 a, a second portion 141 b, and a third portion 141 c. In addition, between the first portion 141a and the third portion 141c, between the second portion 141b and the third portion 141c, the inner peripheral side of the first portion 141a, and the outer periphery of the second portion 141b A light diffusion portion 141 f is formed in the region of the flat portion 141 e corresponding to the side substrate 131. The light diffusion portion 141 f is formed, for example, by applying a concavo-convex pattern. The light diffusion portion 141 f may be formed by another means such as affixing a diffusion sheet or the like. The first portion 141a covers the light emitting elements 133 (the light emitting elements 133L and the light emitting elements 133D in the example of FIG. 4B) in the inner row and controls the light distribution of the light emitting elements 133 in the inner row Do. The third portion 141 c covers the light emitting elements 133 in the middle row (the light emitting element 133 R, the light emitting element 133 G, and the light emitting element 133 B in the example of FIG. Control. The second portion 141b covers the light emitting elements 133 (the light emitting elements 133L and the light emitting elements 133D in the example of FIG. 4B) in the outer peripheral side row, and controls the light distribution of the light emitting elements 133 in the outer peripheral side row. That is, the light distribution control unit 140 according to the embodiment independently controls the light distribution of the light emitting elements 133 arranged in each row for each row.

  Thereby, color unevenness and brightness unevenness on the lower surface (light emitting surface) 150 a of the cover 150 can be reduced, and uniformity of the chromaticity and the brightness can be achieved.

  Here, when the light emitting elements 133 in the outer peripheral row and the light emitting elements 133 in the inner peripheral row are not lighted and only the light emitting elements 133 in the middle row are lighted, the cover 150 depending on the shape of the lens portion 141. A bright line may occur on the lower surface 150a of the More specifically, for example, as indicated by arrows A11 and A12 shown in FIG. 4B, the light emitted from the light emitting elements 133 in the middle row passes through the third portion 141c, and the first portion A bright line may be generated on the lower surface 150 a of the cover 150 when incident on at least one of the 141 a and the second portion 141 b.

  On the other hand, the diffusion processing unit 141 d is provided on the surface of the third portion 141 c of the lens unit 141 of the embodiment. For example, on the surface of the third portion 141c of the lens portion 141, a dot-like scatterer, a so-called embossed pattern is formed. In addition, light of a part of the light incident on the lens portion 141 from the light emitting element 133 and reflected by the emission surface and directed to the flat portion on the back side of the lens portion 141 is Head to the area of the flat portion 141e. If the light diffusion portion 141 f is not formed, light is reflected by the flat portion 141 e of the light distribution control portion 140, and the reflected light is emitted from the lens portion 141. As a result, a bright line is generated, and the bright line is reflected on the cover 150, whereby the uneven brightness of the cover 150 is generated. On the other hand, by forming the light diffusion portion 141 f in the flat portion 141 e of the light distribution control unit 140, light traveling toward the flat portion 141 e is diffused by the light diffusion portion 141 f. Therefore, a bright line with a strong luminous intensity from the lens portion 141 is not generated, and the occurrence of uneven brightness of the cover 150 can be suppressed.

  Thus, as indicated by arrows A13 and A14 shown in FIG. 4B, light transmitted through the third portion 141c is diffused by the diffusion processing portion 141d on the surface of the third portion 141c. Then, the amount of light incident on the first portion 141a and the second portion 141b is reduced. Therefore, generation of bright lines on the lower surface 150 a of the cover 150 can be suppressed. On the other hand, the diffusion processing unit is not provided on the surface of the first portion 141 a and the surface of the second portion 141 b. Therefore, it can suppress that the amount of luminous flux of lighting fixture 100 falls. In the case where the distance between the cover 150 and the lens portion 141 is reduced for the purpose of thinning, etc., the generation of luminance may not be suppressed even if the light diffusion portion 141 f is formed. In this case, diffusion processing may be performed on the incident surface of the lens unit 141.

  As described above with reference to FIG. 2, the substrate 131 is fixed to the lower surface 120 a of the tool body 120. As shown in FIG. 5A, the substrate 131 has a hole 131b. On the other hand, the lower surface 120 a of the instrument body 120 is provided with a protrusion 123 that protrudes downward (light emitting surface side). When attaching the substrate 131 to the lower surface 120 a of the instrument body 120, first, the holes 131 b of the substrate 131 and the protrusions 123 of the instrument body 120 are aligned, and the protrusions 123 of the instrument body 120 are aligned with the holes 131 b of the substrate 131. insert. Thus, the substrate 131 can be temporarily fixed or temporarily placed on the lower surface 120 a of the tool body 120.

  As described above, the light distribution control unit 140 is fixed to the device body 120. As shown in FIG. 5B, the light distribution control unit 140 has a claw portion 143. The claw portion 143 has a wedge shape. The tip end of the claw portion 143 extends in a direction substantially parallel to the lower surface 120 a of the instrument body 120. On the other hand, the instrument body 120 has a hole 125. The length D1 of the hole 125 is longer than the length D2 of the tip of the claw portion 143. When attaching the light distribution control unit 140 to the instrument body 120, first, the positions of the hole 125 of the instrument body 120 and the claw portion 143 are aligned, and the claw portion 143 is inserted into the hole 125 of the instrument body 120. Subsequently, the light distribution control unit 140 is rotated in the direction of the arrow A16 illustrated in FIG. Thus, the light distribution control unit 140 is fixed to the device body 120. More specifically, the claws 143 are hooked on the back side of the tool body 120 and pull the light distribution control unit 140 toward the tool body 120. Thereby, the instrument body 120 and the light distribution control unit 140 are fitted with the substrate 131 held between the instrument body 120 and the light distribution control unit 140.

FIG. 6A to FIG. 6C are graphs showing the relative spectral distribution of light emitted from the light emitting element of the embodiment.
FIG. 6A is a graph illustrating the relative spectral distribution of the light emitting element 133L that emits light of the bulb color (L). FIG. 6B is a graph illustrating the relative spectral distribution of the light emitting element 133G that emits green (G) light. FIG. 6C is a graph illustrating the relative spectral distribution of the light emitting element 133R that emits red (R) light.

  The horizontal axis of the graph represented to Fig.6 (a)-FIG.6 (b) represents wavelength (nanometer: nm). The vertical axes of the graphs shown in FIG. 6A to FIG. 6B represent relative energy.

  As shown in FIG. 6A, the light emitting element 133L that emits light of the bulb color (L) has a peak wavelength in the range of 550 nm to 650 nm. The correlated color temperature of the light of the bulb color (L) emitted by the light emitting element 133L is 2000 Kelvin (K) or more and 3500 K or less.

As shown in FIG. 6B, the light emitting element 133G that emits green (G) light has a peak wavelength in the range of 500 nm or more and 560 nm or less.
As shown in FIG. 6C, the light emitting element 133R that emits red (R) light has a peak wavelength at 600 nm or more. More specifically, the light emitting element 133R that emits red (R) light has a peak wavelength in the range of 620 nm or more and 640 nm or less.

In addition, the light emitting element 133D which emits light of daylight color (D) has a peak wavelength in the range of 440 nm or more and 480 nm or less.
The light emitting element 133B that emits blue (B) light has a peak wavelength in the range of 440 nm or more and 480 nm or less.

FIG. 7 is a block diagram showing the main configuration of the lighting apparatus according to the embodiment.
FIG. 8A and FIG. 8B are schematic plan views showing the remote control transmitter of the embodiment.
The lighting fixture 100 illustrated in FIG. 7 includes a power supply unit 110, a light source unit 130, an indirect light source unit 160, and a control unit 115. The power supply unit 110 is connected to a commercial AC power supply AC. The light source unit 130 is connected to the power supply unit 110.

  The power supply unit 110 functions as a DC power supply, receives a commercial AC power supply AC, and generates a DC output. The light source unit 130 is as described above with reference to FIGS. 1 (a) to 6 (c).

  As shown in FIG. 1B, the indirect light source unit 160 is disposed on the back side (upper side) of the instrument body 120 and has a function of mainly illuminating the ceiling surface. A plurality of indirect light source units 160 are provided around the fitting unit 111, and include a substrate 161 and a plurality of light emitting elements 163. The substrate 161 is formed, for example, in a substantially rectangular flat plate. The light emitting elements 163 are arranged substantially linearly along the longitudinal direction of the substrate 161 and mounted on the substrate 161. The light emitting element 163 emits light of bulb color (L).

  The indirect light source unit 160 is attached to four places on the upper side wall of the power supply unit 110. More specifically, as shown in FIG. 1B, the upper portion of the power supply unit 110 is formed in a substantially square shape. The indirect light source unit 160 is attached to the upper sidewall of the power supply unit 110 having a substantially rectangular shape. Each of the indirect light source units 160 attached at four locations is covered by a cover 165.

  The control unit 115 includes a setting information input / output unit 115a, a light adjustment control unit 115b, and a storage unit 115c. The light adjustment control unit 115 b is connected to the setting information input / output unit 115 a. The storage unit 115c is connected to the setting information input / output unit 115a. A remote control signal reception unit 127 is connected to the setting information input / output unit 115a. A mode storage unit 118a is provided in the storage unit 115c.

  The dimming control means 115b is provided with a PWM control circuit 117a and a switching control circuit 117b. The switching control circuit 117b is connected to the PWM control circuit 117a. As shown in FIG. 7, the PWM control circuit 117 a and the switching control circuit 117 b include a light emitting element 133 L that emits light of a light bulb color (L), a light emitting element 133 D that emits light of a daylight color (D), R), a light emitting element 133 G emitting green (G) light, a light emitting element 133 B emitting blue (B) light, and a light emitting element 163 of the indirect light source unit 160 Is provided for each of. That is, six PWM control circuits 117a and six switching control circuits 117b are provided.

  Thereby, the light source unit 130 and the indirect light source unit 160 can be controlled independently. Moreover, light adjustment control (individual control) for each luminescent color is possible. Therefore, for the light source unit 130, the light control ratio for each light emission color is adjusted to change the light output for each light emission color, and the light bulb color (L), daylight color (D), red color (R), and green color ( A desired emission color can be expressed by mixing the emission colors of G) and blue (B) (individual control mode). For example, the user adjusts the light control ratio for each light emission color by operating at least one of the “R” button 185, the “G” button 186, and the “B” button 187 of the remote control transmitter 180. The light output for each luminescent color can be changed. In the remote control transmitter 180 shown in FIGS. 8A and 8B, the “R” button 185, the “G” button 186, and the “B” button 187 are concealed from the cover portion 180a in the normal state. On the other hand, when the user slides the cover 180a, the cover 180a appears outside.

In the lighting fixture 100 according to the embodiment, a desired mode can be selected and switched among a plurality of lighting modes in order to produce an optical space matched to a life scene. More specifically, in the light emitting element 133 and the light emitting element 163, a plurality of mode setting information (lighting pattern information) in which the light output for each luminescent color is adjusted is stored in the mode storage unit 118a. The user can select the lighting mode stored in the mode storage unit 118a using the remote control transmitter 180, and reproduce the lighting pattern.
For example, the “clean” mode, the “relaxed” mode, the “theater” mode, and the “night break assist” mode (first lighting mode) are set.

  The “beautiful” mode mixes the light emission colors of light bulb color (L), daylight color (D), red color (R), green color (G) and blue color (B), and has high color reproducibility. Expressing the light of daylight color system with excellent color rendering, the table and the color are shown clearly. The average color rendering index (Ra) of mixed light in the “clean” mode is, for example, “95”. For example, the user can select and execute the "clean" mode by pressing the "clean" button 181 of the remote control transmitter 180.

  The “relaxation” mode is a combination of the downward light of the bulb color (L) by the light source unit 130 and the upward light of the bulb color (L) by the indirect light source unit 160 to form the entire bulb space (L) Shine with soft light to create a relaxing and relaxing space. For example, the user can select and execute the "relaxation" mode by pressing the "relaxation" button 182 of the remote control transmitter 180.

  The “theater” mode is illumination by the indirect light source unit 160 using only upward light of a bulb color (L). The "Theater" mode can illuminate the ceiling, create a cinematic experience, and create a light space for enjoying a home theater. For example, the user can select and execute the "theater" mode by pressing the "theater" button 183 of the remote control transmitter 180.

  In the "night break assist" mode, a light emitting element 133D emitting light of daylight color (D) and a light emitting element 133B emitting light of blue (B) are inconspicuous, and a light bulb color (L) and a red (R); Mix the luminescent colors of green (G) and. The "Good Night Assist" mode can achieve a light with a relatively low degree of melatonin suppression, reducing the adverse effects of night lighting on sleep and promoting a good sleep for the user. The average color rendering index (Ra) of mixed light in the "night break assist" mode is relatively high, and the average color rendering evaluation of each of the light bulb color (L) light, red (R) light and green (G) light Higher than the number (Ra). The correlated color temperature of light (mixed light) in which light emission colors of light bulb color (L), red color (R) and green color (G) are mixed in the “night break assist” mode is light of light bulb color (L) Lower than the correlated color temperature. For example, the user can select and execute the “night sleep assist” mode by pressing the “night sleep assist” button 184 of the remote control transmitter 180.

  When reproducing the lighting mode set in this way, the user operates the remote control transmitter 180 to select a specific mode. When the mode selection signal is received by the remote control signal reception unit 127, the received signal is transmitted to the setting information input / output unit 115a. The setting information input / output unit 115a reads the selected mode setting information (lighting pattern information) from the mode storage unit 118a, and transmits the read mode setting information (lighting pattern information) to the light adjustment control unit 115b.

  The PWM control circuit 117a in the light adjustment control means 115b generates a PWM control signal based on the mode setting information and sends it to the switching control circuit 117b. The switching control circuit 117 b performs PWM control based on the PWM control signal, and supplies a DC output from the power supply unit 110 to each light emitting element 133 of the light source unit 130 and the light emitting element 163 of the indirect light source unit 160. As a result, the light emitting elements 133 and 163 of each color are controlled for each light emission color with the light control ratio according to the mode setting information, light is emitted with a predetermined light mixing ratio, and the mixed light emission color is expressed as a whole.

The "good night assistance" mode will be further described with reference to the drawings.
FIG. 9 is a graph showing the relative spectral distribution of the light emitted by the light emitting element in the “night break assist” mode.

  The horizontal axis of the graph shown in FIG. 9 represents a wavelength (nanometer: nm). The vertical axis of the graph shown in FIG. 9 represents relative energy. The relative spectral distribution shown in FIG. 9 includes a light emitting element 133L that emits light of light bulb color (L), a light emitting element 133R that emits light of red (R), and a light emitting element that emits green (G) light The example which mixed light with 133G and the ratio of "0.83: 0.12: 0.05" is represented.

The spectral distribution of the mixed light emitted in the "night break assist" mode has a peak of energy in the wavelength range of 600 nm or more and 650 nm or less. In the relative spectral distribution represented in FIG. 9, there is a peak of energy at a wavelength of 635 nm.
Assuming that the maximum value of the energy of the spectral distribution is “1”, the peak value of energy in the wavelength range of 380 nm or more and 500 nm or less of mixed light emitted in the “night break assist” mode is 0.25 or less. In the relative spectral distribution shown in FIG. 9, the relative energy of the peak in the wavelength range of 380 nm to 500 nm is “0.2”. Assuming that the maximum value of the energy of the spectral distribution is “1”, the peak value of energy in the wavelength range of 530 nm or more and 600 nm or less of mixed light emitted in “night break assist” mode is 0.25 or more and 0.6 or less It is. In the relative spectral distribution shown in FIG. 9, the relative energy of the peak in the wavelength range of 530 nm to 600 nm is “0.48”.

  The average color rendering index (Ra) of the light of the bulb color (L) emitted by the light emitting element 133L is "84". The average color rendering index (Ra) of mixed light of the ratio (0.83: 0.12: 0.05) described above is “93”. That is, the mixed light of the light emitting element 133L that emits the light of the bulb color (L), the light emitting element 133R that emits the light of red (R), and the light emitting element 133G that emits the light of green (G) Compared with the case where light of bulb color (L) is emitted, the average color rendering index (Ra) is increased.

FIG. 10 is a table illustrating the relationship between the light mixing ratio and the degree of melatonin suppression.
FIG. 11 is a graph illustrating the relationship between the dimming ratio of a light-emitting element that emits light of a bulb color and the melatonin suppression relative value.

The inventor mixes a light emitting element 133L that emits light of a bulb color (L), a light emitting element 133R that emits red (R) light, and a light emitting element 133G that emits green (G) light. The relationship between the light ratio (light control ratio) and the melatonin suppression degree was examined. The melatonin suppression degree was calculated by the following equation, using Brainard's melatonin sensitivity curve as Brainard (λ).

Brainard (λ) × relative spectral distribution / V (λ) × relative spectral distribution (1)

"V ((lambda))" in Formula (1) is photopic standard relative luminosity. Further, the melatonin suppression degree when only the light emitting element 133L that emits the light of the bulb color (L) was turned on was "1", and the melatonin suppression degree at each light mixing ratio was represented by a relative value. An example of the result of the examination is as shown in FIG.

  In addition, the inventors set the outputs of the light emitting element 133R that emits red (R) light and the light emitting element 133G that emits green (G) light constant, and emit the light of the bulb color (L). In the case where the light emitting element 133L was dimmed, the relationship between the light mixing ratio of the light emitting element 133L and the melatonin suppression relative value was examined. The melatonin suppression degree at the time of making only the light emitting element 133L which emits the light of bulb color (L) light was made "1", and the melatonin suppression degree in each light mixing ratio of the light emitting element 133L was represented by the relative value. An example of the result of the examination is as shown in FIG.

  According to the table shown in FIG. 10 and the graph shown in FIG. 11, when the light mixing ratio of the light emitting element 133L that emits light of the bulb color (L) is reduced, the melatonin suppression degree is reduced. Here, the light mixing ratio represents a ratio of luminous fluxes of light to be mixed.

  Therefore, in the “night break assist” mode, the control unit 115 according to the embodiment mixes the light emission colors of the light bulb color (L), the red color (R), and the green color (G), and then performs the light bulb color (L). Control to dim only the light emitting element 133L that emits light is executed. Subsequently, when the output of the light emitting element 133L becomes equal to or less than a predetermined value, the control unit 115 executes control to dim the light emitting element 133G and the light emitting element 133R.

  When the light control ratio (light mixing ratio) of the light emitting element 133L that emits light of the bulb color (L) becomes “0.4”, the mixed light deviates from the defined region of the correlated color temperature. If the mixed light deviates from the defined region of the correlated color temperature, the appearance light color may be unnatural. Therefore, when the control unit 115 reduces the light mixing ratio of the light emitting element 133L to "0.5", the light mixing ratio of the light emitting element 133L, the light mixing ratio of the light emitting element 133G, and the light mixing ratio of the light emitting element 133R It is more preferable to execute the control of reducing the light while keeping the light color, that is, keeping the light color, and turning off the light at bedtime.

  According to the embodiment, it is possible to produce an appropriate light space adapted to the life scene. That is, the component of the blue light contained in the mixed light in the "night-rest assist" mode can be relatively reduced, and the degree of melatonin suppression of the occupant can be reduced to promote good sleep. In addition, when the output of the light emitting element 133L becomes equal to or less than a predetermined value, the light emitting element 133G and the light emitting element 133R are dimmed to maintain the light color with reduced discomfort after reducing the blue light component to a predetermined value or less. be able to. Furthermore, mixed light in the "night-rest assist" mode can provide light having a relatively high average color rendering index, and can keep the indoor light color natural.

  As described above with reference to FIGS. 3A and 3B, in the LED package mounted in the inner row, the light emitting element 133L whose light emission color is a light bulb color (L) and the light emission color is a daylight color The light emitting element 133D of (D) is used. The mounting form of the LED packages on the outer circumferential side is similar to the mounting form of the LED packages on the inner circumferential side. The LED package mounted in the middle row includes a light emitting element 133R of red (R) emission color, a light emitting element 133G of green emission color (G), and a light emitting element 133B of blue (B) emission color. And are used.

  Thereby, in the “night break assist” mode, even if the light emitting element 133D emitting light of daylight color (D) and the light emitting element 133B emitting light of blue (B) are turned off, the light is turned off before going to bed The light distribution control unit 140 can suppress the decrease in color tone. Therefore, the light emission color of the light bulb color (L) of the inner row, the red (R) and the green (G) of the middle row, and the light bulb color (L) of the outer row is It is possible to mix colors without generation.

Next, an example of control performed by the control unit 115 of the embodiment will be described with reference to the drawings.
FIG. 12 is an xy chromaticity diagram for explaining an example of control executed by the control unit of the embodiment in the “night sleep assist” mode.

  When the “night break assist” mode is set, the control unit 115 of the embodiment executes control of emitting mixed light of the chromaticity point A shown in FIG. 12. The correlated color temperature of the mixed light of the chromaticity point A is, for example, 2200K. The deviation Δuv from the black body radiation locus of the chromaticity point A is, for example, “0”. Subsequently, the control unit 115 executes control to change the mixed light of the chromaticity point A to the mixed light of the chromaticity point B illustrated in FIG. 12 as time passes. The coordinates (x, y) of the chromaticity point B are, for example, (0.62, 0.36). The color of the mixed light of the chromaticity point B is orange.

  As described above, when the “night-rest assist” mode is set, the control unit 115 according to the embodiment causes the first chromaticity point on the xy chromaticity diagram to have a deviation Δuv from the black body radiation locus of ± 0.02 or less. And performs control of emitting mixed light (first light) of the first chromaticity point that can be expressed by the correlated color temperature. Subsequently, the control unit 115 causes the mixed light of the first chromaticity point to be a region where the y coordinate is 0.32 or more and 0.45 or less and the x coordinate is 0.51 or more on the xy chromaticity diagram. It is A2 and control which changes with time progress to mixed light (second light) of the second chromaticity point inside the area A2 surrounded by the spectrum locus is executed.

  According to this example, by changing the mixed light of the first chromaticity point to the mixed light of the second chromaticity point, the control unit 115 converts the light of low color temperature which is relatively unlikely to disturb sleep to blue. The light component changes to a relatively lower light. For example, the control unit 115 causes the mixed light of the first chromaticity point to be emitted 1 hour before going to bed, and the mixed light of the first chromaticity point to gradually go into the second chromaticity point from 10 minutes before going to bed. Control is performed to reduce the brightness while changing to mixed light and turn off the light at bedtime. According to this, in the initial stage of the “night-rest assist” mode, the light having the chromaticity within the defined region of the correlated color temperature is emitted, so that the sense of discomfort in appearance can be suppressed. Also, from the beginning of the "night break assist" mode to the sleep time (bedtime time), the mixed light of the second chromaticity point in the area A2 of the chromaticity in which the mixed light of the first chromaticity point gradually becomes darker in red By changing it, it is possible to promote natural sleep without suppressing the secretion of melatonin as a hormone that promotes sleep.

Drawing 13 (a) and Drawing 13 (b) are relative spectral distribution explaining the other example of the control which the control part of an embodiment performs in "rest of night assist" mode.
FIG. 13A shows an example of the relative spectral distribution of light before the controller 115 changes the light color. FIG. 13B is an example of the relative spectral distribution of light after the controller 115 changes the light color. The horizontal axes of the graphs shown in FIGS. 13 (a) and 13 (b) represent wavelengths (nanometers: nm). The vertical axes of the graphs shown in FIGS. 13A and 13B represent relative energy.

  When the “night break assist” mode is set, the control unit 115 of the embodiment executes control to emit the first mixed light (first light) represented by the relative spectral distribution in FIG. 13A. . Assuming that the maximum value of the energy of the spectral distribution is “1”, the maximum value of energy in the wavelength range of 500 nm or less of the first mixed light is 0.25 or less. In the example of the relative spectral distribution shown in FIG. 13A, the maximum value of the energy in the wavelength range of 500 nm or less of the first mixed light is “0.14”.

  Subsequently, the control unit 115 executes control to change the first mixed light into a second mixed light (second light) represented by the relative spectral distribution in FIG. 13B as time passes. . Assuming that the maximum value of energy of spectral distribution is “1”, the maximum value of energy in the wavelength range of 500 nm or less of the second mixed light is 0.1 or less. In the example of the relative spectral distribution shown in FIG. 13B, the maximum value of energy in the wavelength range of 500 nm or less of the second mixed light is “0.002”.

  According to this example, by changing the first mixed light to the second mixed light, the control unit 115 further causes the light of low color temperature that is relatively unlikely to disturb sleep, and the blue light component to be relatively more. Change to low light. For example, the control unit 115 causes the first mixed light to be emitted 1 hour before going to bed, and gradually decreases the brightness while changing the first mixed light to the second mixed light 10 minutes before going to bed. Execute control to turn off at bedtime. According to this, since the component of the blue light included in the spectral distribution of the first mixed light is less than or equal to the predetermined value, it is relatively difficult to suppress the secretion of melatonin. In addition, by changing the first mixed light to the second mixed light from the initial stage of the "night break assist" mode to the sleep time (bedtime time), it is possible to realize light with less adverse effects on melatonin suppression. it can.

Drawing 14 (a) and Drawing 14 (b) are xy chromaticity diagrams explaining an example of control which a control part of an embodiment performs.
In the xy chromaticity diagram, the chromaticity coordinates of the light emitting element 133L that emits light of the bulb color (L), the chromaticity coordinates of the light emitting element 133D that emits the light of the daylight color (D), and the light of red (R) The chromaticity coordinates of the light emitting element 133R, the chromaticity coordinates of the light emitting element 133G emitting green (G) light, and the chromaticity coordinates of the light emitting element 133B emitting blue (B) light are shown in FIG. As shown in).

  Here, in the process of performing control to change the lighting state of an arbitrary light mixing ratio to the lighting state of another light mixing ratio, light of an unnatural color is emitted depending on the light mixing ratio of each light emitting element Sometimes. For example, as shown in FIG. 14B, the case of changing from the first lighting state to the second lighting state will be described. In the first lighting state, only the light emitting element 133B that emits blue (B) light is on. In the second lighting state, the light emitting element 133R that emits red (R) light and the light emitting element 133L that emits light of a light bulb color (L) are on. That is, in the second lighting state, mixed light of the light emitting element 133R and the light emitting element 133L is emitted.

  When all the light control of the light emitting element 133L, the light emitting element 133R, and the light emitting element 133B is simultaneously changed when changing from the first lighting state to the second lighting state, the light color is displayed in FIG. It may pass through a high saturation reddish purple area such as the area A3. Then, light of unnatural color unintended by the user may be emitted.

On the other hand, in the embodiment, first, the light emitting element 133L is lit from the first lighting state (first control process). Subsequently, the light emitting element 133B is turned off (second control process). That is, when changing from the first lighting state to the second lighting state, the control unit 115 executes control to dim each light emitting element with a time difference according to the type of light emitting element.
Thereby, it is possible to suppress the emission of light of an unnatural color in the process of performing control to change the lighting state of any light mixing ratio to the lighting state of another light mixing ratio.

For example, the control unit 115 is enabled when changing from a state in which only the chromatic light source is turned on to a state in which only the white light source is turned on or a state in which only the chromatic light source is turned on to a state that the white light source and the chromatic light source are turned on. The control of the white light source is started prior to the control of the colored light source.
For example, when changing from a state in which only the chromatic light source is turned on to another state in which only the chromatic light source is turned on, the control unit 115 performs control of the chromatic light source after turning on the white light source. Execute control to turn off the white light source.

  According to this, since the control of the white light source is started prior to the control of the chromatic color light source, the hue change in the high saturation area is suppressed even if the mixed light state of the chromatic color light source changes thereafter. be able to. Therefore, it is possible to suppress the emission of light of an unnatural color.

For example, when changing the state in which the white light source and the chromatic light source are turned on to another state in which at least one of the white light source and the chromatic light source is turned on, the control unit 115 controls the chromatic light source than the control of the white light source Start running first.
For example, when changing from a state in which only the white light source is turned on to a state in which only the chromatic light source is turned on, the control unit 115 starts executing the control of the chromatic light source prior to the control of the white light source.

  According to this, since the control of the chromatic color light source is started prior to the control of the white light source from the state where the white light source is turned on, it is possible to suppress the change of the hue in the high saturation area. Therefore, it is possible to suppress the emission of light of an unnatural color.

FIG. 15 is an L ^* a ^* b ^* color system for explaining another example of control executed by the control unit of the embodiment.
In the L ^* a ^* b ^* color system, the chromaticity coordinates of the light emitting element 133R that emits red (R) light, the chromaticity coordinates of the light emitting element 133G that emits green (G) light, and blue (B) The chromaticity coordinates of the light emitting element 133B that emits the light of are as shown in FIG. 15, for example.

  As described above with reference to FIGS. 14A and 14B, in the process of performing control to change the lighting state of any mixing ratio to the lighting state of another mixing ratio, mixing of each light emitting element is performed. Depending on the light ratio, light of unnatural color may be emitted. For example, as shown in FIG. 15, the case where the light emitting element 133R emitting light of red (R) is turned on and the light emitting element 133B emitting light of blue (B) is turned on will be described. .

When the output of the light emitting element 133R is gradually lowered and the output of the light emitting element 133B is gradually increased when changing from a state in which only the light emitting element 133R is lit to a state in which only the light emitting element 133B is lit, FIG. As in the first control process, the light color changes slightly on the circumferential side of the straight line connecting the chromaticity coordinates of the light emitting element 133R and the chromaticity coordinates of the light emitting element 133B in the L ^* a ^* b ^* color system. Do. Then, in the first control process, the light color may pass through bright red-purple to give the user an unnatural impression.

On the other hand, in the embodiment, in the process of changing from the state where only the light emitting element 133R is lit to the state where only the light emitting element 133B is lit, the origin of the L ^* a ^* b ^* color system than in the first control process. The control added with green (G) is executed so as to pass through the second control process passing through the area close to. That is, when the control unit 115 changes the first lighting state to the second lighting state, the chromaticity of the light color L ^* a ^* b ^* color system exhibited in the process of change is the first lighting state The control is performed in a region closer to the origin than a straight line connecting the chromaticity coordinates of and the chromaticity coordinates of the second lighting state.

  According to this, in the process of changing the lighting state, since the light color passes through the area of relatively low saturation, it is possible to alleviate the unnaturalness of appearance. In the example shown in FIG. 15, in the second control process, the light color changes from red (R) to red (R) through blue and white from bluish white. Therefore, it is possible to suppress giving an unnatural impression.

FIG. 16 is a flowchart for explaining still another example of control executed by the control unit of the embodiment.
In this example, the case where the "clean" mode, the "relaxed" mode, or the "theater" mode is selected will be described.

  The user operates the “clean” button 181 of the remote control transmitter 180, for example, to select the “clean” mode (step S101). Alternatively, the user operates the “relaxation” button 182 of the remote control transmitter 180, for example, to select the “relaxation” mode (step S103). Alternatively, the user operates the “theater” button 183 of the remote control transmitter 180, for example, to select the “theater” mode (step S105).

  Subsequently, the control unit 115 determines whether the timer function is set (step S107). The timer function in this example is a so-called "off timer function" for sleep, and means a function to turn off the light emitting element 133 after a predetermined time. When the timer function is not set (step S107: No), the control unit 115 continues to determine whether the timer function is set (step S107).

  On the other hand, when the timer function is set (step S107: Yes), the control unit 115 executes the "night sleep assist" mode. The control executed in the "night sleep assist" mode is, for example, as described above with reference to FIGS. 9 to 13 (b). Subsequently, the control unit 115 turns off all the light emitting elements 133 (step S111). As described above, in the example illustrated in FIG. 16, the lighting mode other than the “night-rest assist” mode and the lighting mode (second lighting mode) in which the light output for each luminescent color is previously adjusted is selected. When the timer function is set, the control unit 115 executes control to turn off all the light emitting elements 133 via the “night break assist” mode. In other words, when the lighting function other than the "night sleep assist" mode is selected and the lighting mode in which the light output for each luminescent color is previously adjusted is selected, the control unit 115 is selected when the timer function is set. The control to shift from the lighting mode to the "night break assist" mode is executed. This control is different from the control that only dims and extinguishes the lighting of the "clean" mode, the "relaxing" mode, or the "theater" mode.

  According to this, when the timer function is activated via the "night sleep assist" mode that does not inhibit the sleep onset, for example, even if the lighting mode (for example, the "clean" mode etc.) having the awakening action is set, the sleep onset Can be Therefore, the light which suppresses the bad influence to sleep can be provided.

FIG. 17 is a flowchart illustrating still another example of control executed by the control unit according to the embodiment.
In this example, the case where the "clean" mode, the "relaxed" mode, or the "theater" mode is selected will be described.

  The user operates, for example, the "clean" button 181 of the remote control transmitter 180 to select the "clean" mode (step S121). Alternatively, the user operates the “relaxation” button 182 of the remote control transmitter 180, for example, to select the “relaxation” mode (step S123). Alternatively, the user operates the “theater” button 183 of the remote control transmitter 180, for example, to select the “theater” mode (step S125).

  Then, the control unit 115 disables individual control (step S127). That is, when the lighting mode in which the light output for each luminescent color is adjusted in advance is selected, the control unit 115 adjusts the light control ratio for each luminescent color to vary the light output for each luminescent color. Ban. This makes it possible to suppress that the effect of the specific color-adjustment ratio can not be obtained. In other words, it is possible to hold the setting information of each lighting mode in which the light output for each luminescent color is adjusted in advance.

  In addition, when the "night sleep assist" mode is selected, each light emitting color is within the range of the light bulb color (L), red (R) and green (G) to be lit in the "night sleep assist" mode. The light output ratio of each light emission color may be made variable by adjusting the light control ratio of. That is, in the “night-rest assist” mode, light control and toning may be enabled within the range of light bulb color (L), red (R), and green (G).

  Subsequently, the control unit 115 determines whether the “all light” mode is set (step S129). The “all light” mode is a mode in which the light output of all the light emitting elements 133 of the light bulb color (L) and the daylight color (D) of the light source unit 130 is maximized to mix the light emission colors. The "all light" mode expresses daylight light with excellent color reproduction and excellent color rendering. When the “all light” mode is not set (step S129: No), the control unit 115 continues to determine whether the “all light” mode is set (step S129).

  On the other hand, for example, when the “all light” mode is set by the user operating the “all light” button 189 of the remote control transmitter 180 (see FIGS. 8A and 8B) Step S129: Yes), the control unit 115 cancels the individual control incapability, and enables individual control. The control unit 115 not only cancels the individual control inability when the “all light” mode is set, but also selects the lighting mode (“clean” mode, “relaxed” mode, or “theater” mode) which has been selected. Individual control inability may be released when) is released. Thus, the user operates, for example, the “R” button 185, the “G” button 186, and the “B” button 187 of the remote control transmitter 180 to adjust the light control ratio for each light emission color and Light output can be varied.

It should be noted that the present invention is not limited to this example, and when the "clean" mode, "relaxed" mode, or "theater" mode is selected, red (R) and green (G ) And blue (B) may be separately controlled. Thereby, fine adjustment of red (R), green (G), and blue (B) can be performed within the range of each lighting mode.
Alternatively, when the “clean” mode, the “relaxed” mode, or the “theater” mode is selected, individual control of the light emission color not used in each lighting mode may be enabled. Thereby, fine adjustment of the luminescent color which is not used in each lighting mode can be performed.

FIG. 18 is a flowchart for explaining still another example of control executed by the control unit of the embodiment.
For example, when the user operates the “30 minutes off” button 188 (see FIGS. 8A and 8B) of the remote control transmitter 180 and selects the timer function (step S141), the control unit 115 Control is performed to turn off the main light source first of the light source and the auxiliary light source (step S143). For example, the control unit 115 turns off the light emitting element 133L and the light emitting element 133D. Subsequently, the control unit 115 executes control to turn off the auxiliary light source (step S145). For example, the control unit 115 turns off the light emitting element 133R, the light emitting element 133G, and the light emitting element 133B.
The timer function is as described above with reference to FIG.

  For example, in a case where mixed light of light of bulb color (L), light of red (R), and light of green (G) is emitted, the user can operate the remote control transmitter 180, for example, When the timer function is selected by operating the “off” button 188, the control unit 115 causes the light emitting element 133L to emit light of bulb color (L), the light emitting element 133R to emit red (R) light, and green ( The light emitting element 133L of the light emitting element 133G that emits the light of G) is turned off first. Subsequently, the control unit 115 turns off the light emitting element 133R and the light emitting element 133G.

  According to this, since the illuminance of the main light source is generally higher than the illuminance of the auxiliary light source, the auxiliary light source of relatively low illuminance is turned on before the light is turned off by decreasing the illuminance of the main light source first, The turn-off operation can be performed with relatively low illuminance. Therefore, the light which suppresses the bad influence to sleep can be provided.

FIG. 19 is a flowchart illustrating still another example of control executed by the control unit according to the embodiment.
For example, when the user operates the “30 minutes off” button 188 of the remote control transmitter 180 to select the timer function (step S151), the control unit 115 turns off the auxiliary light source of the main light source and the auxiliary light source first. Control is executed (step S153). For example, the control unit 115 turns off the light emitting element 133R, the light emitting element 133G, and the light emitting element 133B. Subsequently, the control unit 115 executes control to turn off the main light source (step S155). For example, the control unit 115 turns off the light emitting element 133L and the light emitting element 133D.
The timer function is as described above with reference to FIG.

  For example, in a case where mixed light of light of bulb color (L), light of red (R), and light of green (G) is emitted, the user can operate the remote control transmitter 180, for example, When the timer function is selected by operating the “off” button 188, the control unit 115 causes the light emitting element 133L to emit light of bulb color (L), the light emitting element 133R to emit red (R) light, and green ( The light emitting element 133R and the light emitting element 133G among the light emitting elements 133G that emit the light of G) are turned off first. Subsequently, the control unit 115 turns off the light emitting element 133L.

  According to this, for example, when the correlated color temperature of the mixed light of red (R) light and green (G) light gives a sense of discomfort before turning off, the light emitting element 133R and the light emitting element 133G are first. By turning off the light, it is possible to eliminate the discomfort before turning off. In this case, light of bulb color (L) can be provided before extinguishing.

FIG. 20 is a flowchart illustrating still another example of control executed by the control unit according to the embodiment.
In this example, the light emitting element 133L that emits light of a bulb color (L), the light emitting element 133R that emits red (R) light, and the light emitting element 133G that emits green (G) light Explain the case of.

  Circuit components 116 provided inside the chassis of the power supply unit 110 include a sensor (not shown). As a sensor, a human sensor etc. which detect existence of a human are mentioned, for example. Examples of the human sensor include a sensor using infrared light, a sensor using ultrasonic waves, and a sensor using microwaves. The sensor may be attached to the instrument body 120.

  According to the findings obtained by the present inventor, light colors having a relatively low color temperature or correlated color temperature are less likely to disturb sleepiness. Therefore, light having a relatively low color temperature or correlated color temperature is more suitable for lighting for a relatively short time before going to bed or at night. However, in order to realize a light color having a relatively low color temperature or correlated color temperature, it is necessary to use a light emitting element having a relatively low color temperature or correlated color temperature.

  On the other hand, in the example shown in FIG. 20, the light emitting element 133L that emits light of light bulb color (L), the light emitting element 133R that emits light of red (R), and the light of green (G) are emitted. When the light emitting element 133G is turned off (step S161), the control unit 115 determines whether the human sensor has detected a human (step S163). When the human sensor does not detect a human (step S163: No), the control unit 115 continues to determine whether the human sensor has detected a human (step S163).

  On the other hand, when the human sensor detects a human (step S163: Yes), the controller 115 controls the light emitting element 133L that emits the light bulb color (L) and the light emission that emits the red (R) light The element 133R and the light emitting element 133G that emits green (G) light are turned on, and the correlation color temperature is lower than the correlation color temperature in a state where only the light emitting element 133L is turned on. For example, when the human sensor detects a human (step S163: Yes), the control unit 115 executes the "night sleep assist" mode.

  According to this, the lighting fixture 100 according to the embodiment detects a human being and automatically lights up at work at a relatively short time before going to bed or at night. The correlated color temperature of the light color to be lit is lower than the correlated color temperature of the light emitting element 133L that emits the light of the bulb color (L). Therefore, it is possible to realize a light color that does not disturb sleepiness at the time of work for a relatively short time before going to bed or at night. For example, when the user goes to the bathroom at night, it is possible to suppress the inhibition of the second sleeping without the prompting.

Next, a lighting system provided with the lighting fixture 100 according to the embodiment and the detection means will be described.
The lighting system comprises the luminaire 100 as described above with reference to FIGS. 1 (a) to 20 and sensing means. As a detection means, a human sensor, a biometric sensor, an image sensor, a load sensor etc. are mentioned, for example. Examples of the human sensor include a sensor using infrared light, a sensor using ultrasonic waves, and a sensor using microwaves. Examples of the biological sensor include sensors that measure biological information such as pulse waves, electrocardiograms, body temperature, body movement, and blood pressure. As an image sensor, it is an image sensor which has a camera etc., for example, Comprising: The sensor which detects a motion of a person, a motion of eyes, etc. is mentioned.

  In the lighting system according to the embodiment, the sensor detects the behavior of the resident in the bedroom before going to bed, and automatically turns off the lighting fixture 100 after a predetermined time based on the detection result of the sensor. For example, when the sensor detects the resident's behavior before going to bed, the lighting system starts to turn off the lighting apparatus 100 after 5 minutes, and takes about 10 minutes, for example, about 10 minutes so as not to care for the resident. Dim 100 and turn off automatically. Examples of the “pre-sleeping behavior” include the behavior in which the resident enters the bedroom, the behavior in which the resident sits in the bed, the behavior in which he sleeps, the behavior in which he feels sleepy, the behavior in pajamas, There are actions taken out of the bath.

  According to this, when the sensor detects the resident's behavior before going to bed, the lighting apparatus 100 can be automatically turned off after a predetermined time without the resident performing a specific operation.

  Another lighting system according to an embodiment comprises a plurality of lighting fixtures 100 as described above with respect to FIGS. 1 (a) -20. Each of the plurality of lighting devices 100 is provided with an individual control address. The control unit 115 controls at least one of dimming and toning of the plurality of lighting fixtures 100 with a time difference.

  For example, the plurality of lighting devices 100 are disposed from the ceiling to the floor. For example, in the case where the plurality of lighting fixtures 100 are executing the “night break assist” mode, the control unit 115 turns off the light emitting element 133L that emits the light bulb color (L) for 20 minutes from the ceiling to the floor 21 Execute control that takes 22 minutes. Subsequently, the control unit 115 executes control to completely turn off the lighting fixture 100 in 28 minutes, 29 minutes, and 30 minutes. That is, the control unit 115 turns off the light sequentially from the lighting fixture 100 disposed on the ceiling to the lighting fixture 100 installed on the floor. According to this, it is possible to realize time difference dimming which is turned off like the setting of the sun.

  Alternatively, for example, the control unit 115 executes control of mixing the luminescent colors of daylight color (D) and blue color (B). For example, the control unit 115 turns on the light emitting element 133L that emits the light of the light bulb color (L) from the extinguished state of the lighting apparatus 100, and then emits the light of the daylight color (D) The light emitting element 133B that emits the light is turned on to execute at least one of light control and color adjustment. This can prompt the user to wake up.

Alternatively, for example, the plurality of lighting devices 100 are disposed from the ceiling to the floor. For example, when the lighting fixture 100 is in the extinguished state, the control unit 115 turns on the lighting fixture 100 disposed on the floor and the lighting fixture 100 disposed on the ceiling at different times, such as 0 minutes, 1 minute, and 2 minutes. Execute control to start. Subsequently, the control unit 115 turns on the light emitting element 133L, and performs at least one of light control and color adjustment from floor to ceiling after 8, 9, and 10 minutes. Subsequently, the control unit 115 turns on the light emitting element 133D and the light emitting element 133B, and performs at least one of light control and color adjustment from floor to ceiling after 28 minutes, 29 minutes, and 30 minutes. As a result, it is possible to realize time difference dimming which lights up like sunrise.
In addition, the time mentioned above regarding a lighting system is an example, and it is not necessarily limited to this.

  While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 100 luminaire, 110 power supply part, 110a upper surface, 111 fitting part, 113 adapter guide, 115 control part, 115a setting information input / output part, 115b light control control hand, 115c storage means, 116 circuit parts, 117a control circuit, 117b Switching control circuit, 118a mode memory unit, 120 appliance body, 120a lower surface, 121 hole, 123 protrusion, 125 hole, 127 remote control signal receiving unit, 130 light source unit, 131 substrate, 131a lower surface, 131b hole, 133, 133B, 133D , 133G, 133L, 133R light emitting element, 135 electric wire, 137 power supply part, 140 light distribution control part, 141 lens part, 141a first part, 141b second part, 141c third part, 141d diffusion processing part, 141 Flat part, 141f light diffusion part, 143 claw part, 145 convex part, 150 cover, 150 cover, 150 a lower surface, 160 indirect light source part, 161 substrate, 163 light emitting element, 165 cover, 180 remote control transmitter, 180 a cover part, 181 “clean Button, 182 "relaxation" button, 183 "theater" button, 184 "good night assist" button, 185 "R" button, 186 "G" button, 187 "B" button, 188 "30 minutes off" button, 189 " All light button

Claims (1)

Appliance body;
A substrate disposed on the front side of the device body;
A plurality of light emitting elements mounted on the substrate and disposed on the substrate;
A lens unit for covering the plurality of light emitting elements, a lens unit for controlling light distribution of the plurality of light emitting units, and a flat portion facing the substrate between the lens units, and the flat portion is subjected to diffusion processing. A light distribution control unit covering the front surface of the substrate;
A diffusive cover covering the front side of the light distribution control unit;
Equipped with
The plurality of light emitting elements include a white light source and a chromatic color light source, and a lens unit for controlling the light distribution of the chromatic color light source is subjected to diffusion processing .

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