JP2020030928A - Lighting device - Google Patents

Abstract

To provide a lighting device that reduces the difficulty of seeing objects under lighting by adding a blue LED to a daylight or light-bulb LED, and achieves simplification of a control circuit, reduction in the number of circuit components, and downsizing of a power supply board.SOLUTION: A lighting device includes a daylight LED that emits daylight, a light bulb color LED that emits light bulb color light, a blue LED that emits blue light, and a control unit that controls the daylight LED, the bulb LED, and the blue LED, and the control unit controls the daylight LED, the bulb LED, and the blue LED to be simultaneously turned on, and the daylight LED and the bulb LED continuously change the current value individually, and the blue LED controls only turning on and off.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a lighting device including a plurality of color light emitting elements as a light source.

As a ceiling illuminator (so-called ceiling light), a blue LED is added to a state in which daylight-colored and light-bulb-colored light-emitting elements (LEDs: Light Emitting Diodes) are lit at rated output (all-light mode), and 470 nm is added. There has been proposed a device equipped with an “all-light mode + blue LED additional mode” that compensates for the radiation intensity of a wavelength of 〜480 nm and eliminates the difficulty of seeing objects under illumination in the “all-light mode” (Patent Document) 1).
In addition, a blue LED was added to the daylight and bulb color LEDs in a state in which the current was increased by supplying 1.2 times the current in the “all light mode” (brightness up mode). A device that further eliminates the difficulty of seeing an object using the “+ blue LED addition mode” has been proposed (see Patent Document 1).

JP 2016-18680 A

  However, in the lighting device described in Patent Literature 1, there is a description that blue is simply added to daylight color or light bulb color, but the light amount balance and detailed control method are not mentioned. However, the current flowing through the blue LED in the “brightness up mode + blue LED adding mode” is also 1.2 times the current flowing through the blue LED in the “all lighting mode + blue LED adding mode”. Otherwise, it is clear that the same color temperature will not be obtained in each mode. That is, the lighting device described in Patent Document 1 requires not only a daylight LED and a light bulb LED, but also a dimming circuit for varying a current value for a blue LED, which complicates a control circuit and reduces the number of circuit components. There is a concern that the power supply substrate will increase in size.

  The present invention provides a circuit that fixes the current value of a blue LED and controls only lighting and extinguishing, thereby eliminating the complexity of a control circuit, an increase in circuit components, and an increase in the size of a power supply board. It is intended to provide a device.

  The present invention provides a daylight LED that emits daylight light, a light bulb color LED that emits light of bulb color, a blue LED that emits blue light, and a control unit that controls the daylight LED, the light bulb color LED, and the blue LED. Wherein the control unit controls the daylight LED and the bulb LED and the blue LED to light up simultaneously, and the daylight LED and the bulb LED continuously vary the current value individually. And that the blue LED controls only turning on and off.

  According to the present invention, in a lighting device capable of eliminating the difficulty of seeing an object under illumination using daylight or light bulb color, a control unit of a power supply circuit is simplified, the number of circuit components is reduced, and a power supply board is reduced. Miniaturization can be realized.

It is an exploded perspective view showing the LED lighting device according to the first embodiment. It is a top view showing arrangement of each color LED of the LED lighting device concerning a 1st embodiment. It is a top view showing arrangement of each color LED of the LED lighting device concerning a modification of a 1st embodiment. It is a longitudinal section showing an LED lighting device concerning a 1st embodiment. FIG. 2 is a control block diagram illustrating the LED lighting device according to the first embodiment. (A) is a spectrum distribution diagram of a daylight LED, (b) is a spectrum distribution diagram of a bulb color LED, and (c) is a spectrum distribution diagram of a blue LED. (A) is a spectrum distribution diagram obtained by superposing the spectrum distribution diagrams of (a) and (b) of FIG. 6 and all the lamps, and (b) is a spectrum distribution diagram of sunlight and FIG. FIG. 6C shows a spectrum distribution diagram obtained by superimposing a spectrum distribution diagram and a spectrum distribution diagram obtained when blue LEDs are added to all lamps, and FIG. FIG. 7 is a spectrum distribution diagram obtained by superimposing a spectrum distribution diagram when a blue LED is added. FIG. 4 is a pattern diagram showing a relationship between a color temperature and a light flux. It is a table | surface which shows legibility of characters etc. for every mode type. It is an exploded perspective view showing the LED lighting device concerning a 2nd embodiment. It is a perspective sectional view showing the LED lighting device concerning a 2nd embodiment. It is the A section enlarged view of FIG.

  Hereinafter, an LED lighting device (LED ceiling light) according to an embodiment of the present invention will be described in detail with reference to the drawings. Note that the LED lighting devices 1A and 1B according to the present embodiment are provided via a mounting adapter (not shown) that engages with an indoor wiring device (not shown) such as a hanging rosette or a hanging ceiling provided on a ceiling surface of a house. Thus, it is connected to an external power supply and fixed at a predetermined position on the ceiling surface for use.

(1st Embodiment)
FIG. 1 is an exploded perspective view showing the LED lighting device according to the first embodiment. In FIG. 1, the upper side of the drawing is the ceiling side, and the lower side of the drawing is the floor side.

  As shown in FIG. 1, the LED lighting device 1A is, for example, a round shape, and has a main body base 11, an adapter receiving portion (insulating material) 12, a power supply board 13, a heat sink 14, a LED light source board 15A, and a reflection sheet 16. , An LED cover 17, a center cover 18, a shade 19, a ring member 20, a sensor unit 21, and the like.

  The main body base 11 is a component formed by processing a steel plate (for example, SPCC) into a substantially circular shape, and is formed in a substantially concave shape (dish shape) such that the concave surface faces the floor side. In the center of the main body base 11, an adapter mounting hole 11a for locking a mounting adapter (not shown) is formed.

  The adapter receiving portion (insulating material) 12 is formed of a synthetic resin having flame retardancy (for example, PBT: polybutylene terephthalate resin), and has a ring-shaped fixing portion 12 a screwed to the main body base 11, And a cylindrical portion 12b extending downward (downward) from an inner peripheral edge of the inner peripheral portion 12a.

  The power supply board 13 includes a lighting circuit board including a control unit and the like, and is fixed to the main body base 11 via an adapter receiving unit (insulating material) 12 with screws. As a result, the power supply board 13 is disposed in a heat dissipation space surrounded by the main body base 11 and a heat dissipation plate 14 described later while maintaining electrical insulation.

  The power supply board 13 is electrically connected to a mounting adapter (not shown) via an electric wire (not shown). Thus, the LED lighting device 1A is supplied with power via the indoor wiring device (not shown), the mounting adapter (not shown), and the power supply board 13, respectively.

  The heat radiating plate 14 is formed by processing a steel plate into a substantially circular shape, and has a truncated conical substrate supporting portion 14a protruding toward the floor. Further, the heat radiating plate 14 is made of a metal having good thermal conductivity such as a galvanized steel plate, for example, and is squeezed to increase strength. Further, the heat radiating plate 14 is formed to have a larger diameter than the main body base 11 and is attached to the main body base 11 so as to protrude radially outward from the main body base 11.

  A circular through hole 14b is formed at a position corresponding to the cylindrical portion 12b of the adapter receiving portion (insulating material) 12 at the center of the heat sink 14 in the radial direction. Further, on the annular portion 14c formed on the outer periphery of the heat radiating plate 14, receiving members 14d for hanging the shades 19 described later are attached at three positions at 120 ° intervals.

  The LED light source board 15A includes a ring-shaped wiring board 15a and a plurality of LED element groups 15b concentrically arranged on one surface side (floor side) of the wiring board 15a. The details of the LED element group 15b will be described later.

  The wiring board 15a is formed, for example, by forming an insulating layer and a copper foil pattern on a substantially annular metal plate made of an aluminum alloy, or on a flat plate of a resin (for example, a polyimide resin) having good heat conductivity. It is formed by forming a copper foil pattern and a solder resist. The wiring board 15a is fixed to the heat sink 14 with screws.

  In the present embodiment, by providing the main body base 11 and the radiator plate 14 having the above-described configurations, the volume of the radiator space is increased (the amount of air in the radiator space is increased), and the power supply board 13 and the LED light source board are provided. The heat radiation efficiency of 15A is improved. As a result, the luminous efficiency of the LED element group 15b can be increased.

  FIG. 2 is a plan view showing the arrangement of each color LED of the LED lighting device according to the first embodiment. FIG. 2 shows an example of an array pattern of LEDs for 18 tatami mats.

  As shown in FIG. 2, the LED element group 15b includes a plurality of daylighting LEDs (Light Emitting Diodes) 15b1 that emit daylight (D color) light, and a plurality of bulb color LEDs 15b2 that emit light of the bulb color (L color). , And a plurality of blue LEDs 15b3 that emit blue light. The LED element group 15b includes an LED 15b4 for security light.

  The daylight LED 15b1 has a peak wavelength of 430 nm to 460 nm (see FIG. 6A described later), and is formed in a plurality of rows (9 rows in the embodiment of FIG. 2) concentrically from the outer circumference to the inner circumference. ing.

  The light bulb color LED 15b2 has a peak wavelength of 550 nm to 650 nm, and is arranged in a plurality of concentrically arranged rows with the daylight LED 15b1 interposed therebetween. In other words, the bulb color LEDs 15b2 are arranged in each row of the concentric circles with two daylight LED 15b1 interposed therebetween in the circumferential direction. Note that the bulb color LEDs 15b2 in the second row from the inner peripheral side are arranged with one or two daylight LED 15b1 interposed therebetween. The daylight LED 15b1 and the bulb LED 15b2 are arranged at equal or substantially equal intervals in the circumferential direction in each concentric row.

  The blue LED 15b3 has a peak wavelength of 470 nm to 480 nm, and is annularly spaced apart in the circumferential direction between the outermost and innermost circumferences of the daylight LED 15b1 and the bulb-color LED 15b2 arranged concentrically in a plurality of rows. Are located in In the embodiment of FIG. 2, the row in which the daylight LED 15b1 and the bulb color LED 15b2 are arranged is arranged in five concentric circles on the inner peripheral side of the annularly arranged blue LED 15b3, and concentrically on the outer peripheral side. It has a column arrangement.

  FIG. 3 is a plan view illustrating an arrangement of LEDs of each color of the LED lighting device according to the modification of the first embodiment. The LED light source board 15B shown in FIG. 3 shows an array pattern of LEDs for 8 tatami mats, and differs from the LED light source board 15A only in the number and arrangement of the LED element groups 15b. Are identical. The security light LED 15b4 is arranged at the same position regardless of the number of tatami mats.

  As shown in FIG. 3, the daylight LED 15b1 has the same peak wavelength as described above, and is formed in a plurality of rows (six rows in the embodiment of FIG. 3) concentrically from the outer circumference to the inner circumference. .

  The bulb color LED 15b2 has the same peak wavelength as described above, and is arranged in each row arranged concentrically with the daylight LED 15b1 interposed therebetween.

  The blue LED 15b3 has a peak wavelength similar to that described above, and is spaced apart in the circumferential direction between the outermost and innermost circumferences of the daylight LED 15b1 and the bulb LED 15b2 arranged concentrically in a plurality of rows. They are arranged in a ring. In the embodiment of FIG. 3, the row in which the daylight LED 15b1 and the bulb color LED 15b2 are arranged is concentrically arranged in three rows on the inner peripheral side of the annularly arranged blue LED 15b3, and concentrically on the outer peripheral side. It has a column arrangement.

  The LED element group 15b illustrated in FIG. 2 includes, for example, 275 daylight LEDs 15b1, 142 bulb-color LEDs 15b2, and 41 blue LEDs 15b3. The LED element group 15b illustrated in FIG. 3 includes, for example, 148 daylight LEDs 15b1, 76 bulb LEDs 15b2, and 23 blue LEDs 15b3. Thus, the number of blue LEDs 15b3 is preferably about 10% of the total number of daylight LED 15b1 and bulb color LED 15b2.

  Returning to FIG. 1, the reflection sheet (reflection film) 16 has a function of reflecting light emitted from the LED element group 15b toward the ceiling (light reflected toward the ceiling by the LED cover 17 and the shade 19) toward the floor. And is formed in a donut shape (annular shape) in plan view so as to correspond to the shape of the LED light source substrate 15A. The reflection sheet 16 is formed of a white resin sheet, and has a through hole 16a for individually exposing (inserting) each element of the LED element group 15b. In the present embodiment, the case where the reflection sheet 16 is provided has been described as an example. However, the present invention is not limited to this, and a high reflection coating may be applied to the heat sink 14 and the light source substrate 15A. . In the present embodiment, by using the reflection sheet 16 instead of the high reflection coating, the LED lighting device 1A can be manufactured at low cost.

  The LED cover 17 has a function of guiding the light flux emitted from the plurality of LED element groups 15b to the front side (floor side), a function of pressing the LED light source substrate 15A so as to be in close contact with the heat sink 14, and the like. I have.

  The LED cover 17 is integrally formed by injection molding or the like using a resin having translucency and electrical insulation, such as polystyrene and polycarbonate. In particular, it is preferable to use polystyrene in terms of transparency, cost, and moldability. The material used for the LED cover 17 is not limited to resin as long as it has translucency and electrical insulation, and may be glass or the like.

  The LED cover 17 includes a substantially circular LED cover 17a that covers the entire light emitting surface (the surface on which the LED element group 15b is mounted) of the LED light source substrate 15A, and a rear side from the outer peripheral edge of the LED cover 17a. It has a cylindrical wall portion 17b extending toward the (ceiling side) and a flange portion 17c projecting radially outward from the upper end (back side) of the wall portion 17b. The flange portion 17c extends in the circumferential direction and is formed by being divided into three portions.

  The center cover 18 covers a mounting adapter (not shown) exposed at the center of the apparatus main body, and is made of, for example, synthetic resin having flame retardancy (for example, PP: polypropylene resin). The center cover 18 is formed in a disk shape and is detachably attached to the LED cover 17.

  The seed 19 is made of a resin (for example, acrylic or polystyrene) having translucency (including transparent, translucent, or milky white), and is configured in a dome shape. In addition, the shade 19 diffuses the light beam emitted from the light source (the LED element group 15b) to reduce glare when the user looks directly at the LED lighting device 1A, or the LED lighting device 1A is installed. It plays a role in equalizing the brightness of the space. Further, the shade 19 is detachably engaged and held by the receiving member 14d of the heat sink 14.

  The ring member 20 is configured such that the inner peripheral side of the ring portion is held on the outer peripheral side of the shade 19, and the outer peripheral side of the ring portion projects outside the outer periphery of the shade 19. Further, the ring member 20 is formed of a material having a light transmitting property.

  The sensor unit 21 changes power supplied to the LED element group 15b in accordance with, for example, the brightness of the environment (space) in which the LED lighting device 1A is installed, and obtains a constant illuminance under the LED lighting device 1A. Provide a function to make it. Further, the illuminance under the LED lighting device 1A is detected.

  FIG. 4 is a longitudinal sectional view showing the LED lighting device according to the first embodiment.

  As shown in FIG. 4 (also as shown in FIG. 1), the LED cover portion 17a has a circular through hole 17a1 formed at the center in the radial direction. In the LED cover 17a, a dome-shaped portion 17a2 is formed at a position corresponding to each of the LED element group 15b (daylight LED 15b1, bulb LED 15b2, blue LED 15b3) of the LED light source substrate 15A. The dome-shaped portion 17a2 has a lens function and diffuses light beams from the daylight LED 15b1, the bulb LED 15b2, and the blue LED 15b3.

  In the LED cover 17, the LED cover portion 17a is fixed to the substrate supporting portion 14a of the heat sink 14 by screws, and the flange portion 17c is fixed to the annular portion 14c of the heat sink 14 by screws.

  The wall 17b extends in a direction substantially perpendicular to the LED cover 17a. A notch (not shown) is formed in the wall portion 17b so that heat in the LED cover 17 can be released to the outside. Note that the opening area of the notch is set to a size that does not allow a user's finger to be inserted. This can prevent the user from directly touching the LED light source substrate 15A with his / her hand (finger).

  The flange portion 17c is a fixing portion that fixes the LED cover 17 to the heat sink 14 on the outer peripheral side of the LED light source substrate 15A.

  FIG. 5 is a control block diagram illustrating the LED lighting device according to the first embodiment.

  As shown in FIG. 5, the LED lighting apparatus 1A operates by being supplied with power from a power supply PS (or a commercial power supply) and a power supply circuit 130. The power supply circuit 130 has a function of adjusting the power of the power supply PS to a predetermined voltage or current.

  The LED lighting device 1A includes a light receiving unit 110. The light receiving unit 110 has a function of receiving a signal (for example, infrared light) output from the remote control 120 by operating a button on the remote control 120 and transmitting the received signal to the control unit 101.

  Remote controller 120 has a button (not shown) operated by a person, and has a function of outputting a signal set for the operated button. For example, it is possible to set an all-light mode, a brightness increase mode, a blue LED addition mode, a brightness increase mode + a blue LED addition mode, and the like.

  Next, a functional example of the LED lighting device 1A will be described. The LED lighting apparatus 1A includes a control unit 101, dimming circuits 102 and 103 for dimming a daylight LED and a bulb LED, a lighting circuit 104 for turning on and off a blue LED, and three types of daylight LEDs 15b1, a bulb LED 15b2, and a blue LED, respectively. It has an LED 15b3 (light source). The illustration of the security LED 15b4 described with reference to FIGS. 2 and 3 is omitted.

  The control unit 101 includes a microcomputer and the like, and has a function of receiving a signal received by the light receiving unit 110 and generating a control signal for controlling the dimming circuits 102 and 103 and the lighting circuit 104. The control signal is, for example, a PWM (Pulse Width Modulation) signal. The control unit 101 is constituted by a CPU (Central Processing Unit) and a main memory, and develops an application program stored in a storage unit (not shown) in the main memory to realize its function.

  The dimming circuits 102 and 103 drive the daylight LED 15b1 and the bulb LED 15b2 based on the control signal received from the control unit 101, and the lighting circuit 104 has a function of driving the blue LED 15b3. Further, the dimming circuits 102 and 103 have a function of individually changing the drive current for driving the daylight LED 15b1 and the bulb LED 15b2 based on the control signal received from the control unit 101. In addition, the lighting circuit 104 has a simple function that has a function of switching between a lighting state and a non-lighting state of a blue LED based on a control signal received from the control unit 101 and does not have a function of changing a driving current.

  6A is a spectrum distribution diagram of a daylight LED, FIG. 6B is a spectrum distribution diagram of a bulb color LED, and FIG. 6C is a spectrum distribution diagram of a blue LED. Note that, in the present embodiment, the relationship between the wavelength (WAVELENGTH (nm)) and the radiation intensity will be described as a spectrum distribution diagram, but a waveform having a similar peak wavelength is also shown in the relationship between the wavelength and the energy ratio. Things.

  As shown in FIG. 6A, the daylight LED 15b1 has a peak wavelength in the range of 430 nm to 460 nm. In the present embodiment, the LED having the peak wavelength at 450 nm is used. The color temperature of the daylight LED 15b1 is 6500K (Kelvin).

  As shown in FIG. 6B, the bulb color LED 15b2 has a peak wavelength in the range of 550 nm to 650 nm, and in the present embodiment, the LED having the peak wavelength at 610 nm is used. The color temperature of the bulb color LED 15b2 is 2700K.

  Note that the color temperatures of the daylight LED 15b1 and the bulb color LED 15b2 are not limited to 6500K or 2700K.

  As shown in FIG. 6C, the blue LED 15b3 has a peak wavelength in the range of 470 nm to 480 nm. In the present embodiment, a blue LED having a peak wavelength of 475 nm is used.

  FIG. 7A is a spectrum distribution diagram in which FIGS. 6A and 6B are superimposed with the spectrum distribution diagrams of all lamps, and FIG. 7B is a spectrum distribution diagram of sunlight and FIG. ), The spectrum distribution diagram of all the lamps, and the spectrum distribution diagram in the case where a blue LED is added to all the lamps, and FIG. 7C shows the spectrum distribution of FIG. FIG. 4 is a spectrum distribution diagram obtained by superimposing a diagram and a spectrum distribution diagram when a blue LED is added to the brightness increasing mode.

  Meanwhile, it is known that the sensitivity of humans to light changes with age, and in particular, the sensitivity of elderly people to light in the short wavelength region (about 500 nm or less) decreases. In a lighting device using a white LED as a light source, as shown in FIG. 7A, the characteristics of the daylight LED 15b1 and the bulb LED 15b2 are substantially the same in the wavelength-radiation intensity characteristics, and both are near the wavelength of 470 nm to 480 nm. Radiation intensity is low. Further, even in the full-light mode (6099 lm, 4800K) in which both the daylight LED 15b1 and the bulb color LED 15b2 are simultaneously turned on, the characteristics are substantially the same, and the radiation intensity is low near the wavelength of 470 nm to 480 nm. For this reason, there is a problem that it is difficult for elderly people to see colors and characters mainly containing short-wavelength light components such as blue under LED illumination.

  Therefore, in the present embodiment, as shown by the bold solid line in FIG. 7B, the blue LED 15b3 is additionally lit in the all-light mode in which the daylight LED 15b1 and the bulb color LED 15b2 are lit simultaneously (in addition). That is, by simultaneously turning on the daylight LED 15b1, the bulb color LED 15b2, and the blue LED 15b3, it is possible to improve the drop of the radiation intensity at 470 nm to 480 nm. As a result, the color temperature can be approximated to the waveform of the spectrum of sunlight at 5800 K, and characters such as written characters can be easily viewed.

  FIG. 8 is a pattern diagram showing the relationship between the color temperature and the luminous flux. The horizontal axis in FIG. 8 represents the color temperature (K), and the vertical axis represents the luminous flux (lm: lumen).

  A point 200 in FIG. 8 is a maximum value of the brightness range of the room determined by the Japan Lighting Manufacturers Association according to the number of tatami mats (hereinafter, “maximum luminous flux suitable for the size of the room”). ). At this point 200, the current values given to the daylight LED 15b1 and the bulb LED 15b2 have a certain margin with respect to their ratings.

  An area 250 with a dot represents a range in which one or both of toning and dimming can be performed in the normal mode.

  A point 210 represents the luminous flux and the color temperature when the control unit 101 receives the instruction of “brightness up mode” for increasing the luminous flux further than the point 200. When the control unit 101 receives the instruction of the brightness increasing mode, for example, in the “all-lights mode” (rated output), the control unit 101 causes a current of 1.2 times the current value to flow to the daylight LED 15b1 and the bulb color LED 15b2. To control. The color temperature at point 210 is the same as the color temperature at point 200. Since the luminous flux at the point 210 is increasing at each of the plurality of daylight LEDs 15b1 and the plurality of bulb LEDs 15b2, the amount of increase in the dimming rate or current value per one LED depends on some of the daylight LEDs 15b1 and the bulb color. The number of luminous fluxes can be reduced by the same amount in the LED 15b2.

  Point 221 is the “fluorescent mode” obtained when the daylight LED 15b1 is driven alone. A point 222 is a “light bulb color mode” obtained when the light bulb color LED 15b2 is driven alone.

  A point 223 is a “lighting mode of a library” obtained by toning the daylight LED 15b1 and the bulb LED 15b2. In the “library light mode”, the color temperature is set to 5000 K which is lower than the fluorescent lamp mode and higher than the bulb mode, and the luminous flux is set to 5900 lm which is higher than the fluorescent lamp mode and the bulb mode.

  A point 224 is a “dining table mode” obtained by toning the daylight LED 15b1 and the bulb LED 15b2. In the “dining table mode”, the color temperature is set to 3000 K, which is lower than the fluorescent lamp mode and higher than the bulb mode, and the luminous flux is set to about 3650 lm, which is lower than the fluorescent lamp mode and higher than the bulb mode.

  As described above, the “fluorescent light mode”, the “bulb color mode”, the “library light mode”, and the “dining table mode” also have substantially the same characteristics as the “all light mode”, and have a wavelength of 470 nm to 480 nm. It has the characteristic that the radiation intensity decreases in the vicinity.

  Therefore, in the present embodiment, as indicated by an arrow 230 in FIG. 8, the “all-light mode + blue-LED addition mode” of the point 220 to be turned on by adding the blue LED 15b3 to the “all-light mode” of the point 200 is added. Thus, it is possible to obtain light of 5600K such that the color temperature approaches 5800K of sunlight, so that it is possible to obtain an effect that characters and the like can be easily viewed.

  Also, in the “all-light mode”, even in the “brightness up mode” in which a 1.2-fold current is applied to the daylight LED 15b1 and the bulb-color LED 15b2, there is a characteristic that the radiation intensity decreases at a wavelength near 470 nm to 480 nm. .

  Therefore, in the present embodiment, as indicated by an arrow 231 in FIG. 8, a “brightness up mode + blue LED addition mode” of a point 240 that is turned on by adding the blue LED 15b3 to the “brightness up mode” of the point 210 is added. By adding, it is possible to obtain an effect that characters and the like can be more easily seen when the color temperature approaches 5800K of sunlight, and an effect that objects can be easily seen.

  Here, “all light mode” at point 200, “brightness up mode” at point 210, “all light mode + blue LED addition mode” at point 220, and “brightness up mode + blue LED addition mode” at point 240 A method for realizing the method and the light amount ratio of each of the daylight LED 15b1, the bulb LED 15b2, and the blue LED 15b3 will be described.

  In the above description, in the “all light mode” of the point 200, the current that is 1.2 times the current flowing through the daylight LED 15b1 and the bulb color LED 15b2 flows in the “brightness up mode” of the point 210. In order to facilitate the description, the following description will be made on the assumption that when the current is 1.2 times the amount of light can be obtained 1.2 times without considering the current characteristics and temperature characteristics of each LED.

  First, in order to realize the above-mentioned light of 6099 lm and 4800 K in the “all light mode” at the point 200, the light amount of the daylight LED 15b1 is about 3900 lm and the light amount of the bulb color LED 15b2 is about 2200 lm. Assuming that the light amount of the bulb color LED 15b2 is 100, the light amount of the daylight LED 15b1 is 177.

  In the "brightness up mode" of the point 210, it is simply 1.2 times that of the "all light mode" of the point 200, so that the light quantity of the bulb color LED 15b2 is 120 and the light quantity of the daylight LED 15b1 is 212, It is possible to increase the brightness 1.2 times while maintaining the color temperature of 4800K.

  In the “all light mode + blue LED addition mode” at point 220, in order to realize the above-mentioned 5600K, the light quantity of the blue LED 15b3 is 7.5 (for the light quantity 100 of the bulb color LED 15b2 and the light quantity 177 of the daylight LED 15b1). About 165 lm for the above-mentioned light flux is sufficient.

  In order to realize the “brightness up mode + blue LED addition mode” at the point 240, in addition to the light amount 120 of the bulb color LED 15 b 2 and the light amount 212 of the daylight LED 15 b 1, the light amount of the blue LED 15 b 3 is the light amount at the point 220. If the value is 9.0, which is 1.2 times the value of 5, the same color temperature of 5600K can be realized.

  However, if this control method is used, a third dimming circuit controls the driving current of the blue LED 15b3 in addition to the dimming circuit 102 that controls the driving current of the daylight LED 15b1 and the dimming circuit 103 that controls the driving current of the bulb color LED 15b2. The dimming circuit (not shown) is required, and since the three LEDs are individually controlled, the control circuit becomes complicated, the number of circuit components increases, and the power supply board becomes large.

  Here, the light quantity of the daylight LED 15b1 is increased to 222, the light quantity of the light bulb color LED 15b2 is reduced to 112, and the light quantity of the blue LED 15b3 is optimized by optimization. It is possible to realize the “brightness up mode + blue LED addition mode” of the point 240 even while maintaining 0.5.

  By optimizing the light amount ratio between the daylight LED 15b1 and the light bulb color LED 15b2, if there is a lighting circuit 104 having a function of simply switching on and off the blue LED 15b3, a dimming circuit for performing complicated control is unnecessary. Becomes

  Therefore, the control circuit can be simplified, the number of circuit components can be reduced, and the size of the power supply board can be reduced.

  Note that the light amount ratio described above is merely an example, and the light amount ratio is not limited to the above light amount ratio because the optimum ratio differs depending on the characteristics of the daylight LED 15b1, the bulb color LED 15b2, and the blue LED 15b3 used.

  FIG. 9 is a table showing legibility of characters and the like for each mode type. In FIG. 9, “○” indicates “easy to see”, one “、” indicates “easy to see”, and “◎◎” indicates “easy to see”.

  In FIG. No. 1 is “bulb color mode”; No. 2 is “dining table mode”; No. 3 is “light mode of library”, No. 3 No. 4 is a “fluorescent light mode”; Reference numeral 5 denotes an "all light mode". No. 1 to No. In No. 5, the result was “easy to see”.

  Also, in FIG. Reference numeral 6 denotes a "brightness up mode" (1.2 times the current value of the "all light mode"). In this case, the result of "easier to see" was obtained.

  Also, in FIG. No. 7 describes a plurality of modes collectively. When “blue LED addition mode” is added to “bulb color mode” of No. 1 When “blue LED addition mode” is added to “dining table mode” of No. 2, When “blue LED addition mode” is added to “library light mode” of No. 3, When the “blue LED addition mode” is added to the “fluorescent lamp mode” of No. 4, This is a case where “blue LED addition mode” is added to “all light mode” of No. 5. For these, no. 1 to No. With respect to the mode 5 (without the addition of the blue LED 15b3), the result was “easier to see”. In these “bulb color mode + blue LED addition mode”, “dining table mode + blue LED addition mode”, “library light mode + blue LED addition mode”, and “fluorescent light mode + blue LED addition mode”, the wavelength of 470 nm to 480 nm is set. The portion with low radiation intensity can be complemented, and by adding a blue LED 15b3 to each mode, Since the radiation intensity in the range of 470 nm to 480 nm can be made close to the waveform of sunlight (5800K) at 470 nm to 480 nm without increasing the current value by 1.2 times as in 6, characters and the like can be easily seen.

  Also, in FIG. No. 8 is No. This is a case where a “blue LED addition mode” is added to the “brightness up mode” of No. 6. In this case, a result of "even easier to see" was obtained for the "brightness up mode" (without the addition of the blue LED 15b3).

  As described above, the LED lighting device 1A of the first embodiment includes the daylight LED 15b1, the bulb LED 15b2, the blue LED 15b3, and the control unit 101 that controls the daylight LED 15b1, the bulb LED 15b2, and the blue LED 15b3. Driving the blue LED 15b3 by optimizing the light quantity ratio between the daylight LED 15b1 and the bulb LED 15b2 by the dimming circuit 102 for controlling the driving current of the daylight LED 15b1 and the dimming circuit 103 for controlling the driving current of the bulb LED 15b2. Can be controlled only by a simple lighting circuit 104 of only lighting / extinguishing, and a brightness of 1.2 times (predetermined magnification larger than 1) of the full lighting mode in which the daylight LED 15b1 and the bulb color LED 15b2 are driven at the rated output. Blue L By additionally lighting D15b3, it is possible to supplement the region where the radiation intensity of the wavelength of 470 nm to 480 nm is reduced, and to make the color temperature close to 5800K of sunlight, so that characters and the like are easy to see. While maintaining this, it is possible to simplify the control circuit, reduce the number of circuit components, and reduce the size of the power supply board.

(2nd Embodiment)
FIG. 10 is an exploded perspective view showing the LED lighting device according to the second embodiment.

  As shown in FIG. 10, the LED lighting device 1B (lighting device) includes a main body base 111, an adapter receiving portion (insulating material) 112, a power supply board 113, a heat sink 114, a first LED light source board 115, an LED cover 116, and a reflection sheet. 117, a light blocking member 118, a security light cover 119, a second LED light source substrate 121, a center cover 122, a sensor unit 123, a light guide plate (light guide) 131, a ring cover 132, a light guide piece 133 (light guide), and the like. Have been.

  The main body base 111 is a component formed by processing a steel plate (for example, SPCC) into a substantially circular shape, and is formed in a substantially concave shape so that the concave surface faces the side. In the center of the main body base 111, an adapter mounting hole 111a for locking a mounting adapter (not shown) is formed.

Further, a ring-shaped packing 111b is adhesively fixed to the upper surface of the main body base 111. The packing 111b seals a gap between the main body base 111 and the ceiling surface, thereby preventing dust or the like from entering the apparatus main body.

  The adapter receiving portion (insulating material) 112 is formed of a flame-retardant synthetic resin (for example, PBT: polybutyne terephthalate resin), and has a ring-shaped fixing portion 112 a fixed to the main body base 111, and the fixing portion 112 a And a cylindrical portion 112b extending downward (downward) from the inner peripheral edge portion. A locking hole 112c for locking a security light cover 119 described later is formed in the cylindrical portion 112b.

  The power supply board 113 has a lighting circuit board and the like, and is fixed to the main body base 111 via an insulating plate (not shown). The insulating plate is formed of a resin material having electrical insulation and flame retardancy, such as polypropylene. As a result, the power supply board 113 is disposed in a heat radiation space surrounded by the main body base 111 and a heat radiation plate 114 described later while maintaining electrical insulation.

  The power supply board 113 is electrically connected to a mounting adapter (not shown) via an electric wire (not shown). Thereby, the LED lighting device 1B is supplied with power via the indoor wiring device (not shown), the mounting adapter (not shown), and the power supply board 113, respectively.

  The heat radiating plate 114 is formed by processing a steel plate into a substantially circular shape, and is made of, for example, a metal having good thermal conductivity such as a galvanized steel plate. Further, the heat radiating plate 114 is formed to have a larger diameter than the main body base 111, and is attached to the main body base 111 so as to protrude radially outward from the main body base 111.

  Further, a circular through hole 114 a is formed at a position corresponding to the cylindrical portion 112 b of the adapter receiving portion (insulating material) 112 at a radial center of the heat radiating plate 114. Further, a plurality of screw holes 114b for screwing a first LED light source substrate 115 described later are formed in the outer peripheral portion of the heat sink 114 at a plurality of positions along the circumferential direction. On the outer peripheral side of the screw hole 114b of the heat radiating plate 114, a plurality of hook holes 114c, 114c for holding a receiving member 140 described later are formed. The hook holes 114c, 114c are arranged at 120 ° intervals in the circumferential direction. In the heat radiating plate 114, screw holes 114d for screwing the receiving member 140 to the heat radiating plate 114 are formed near the hook holes 114c. The strength of the heat radiating plate 114 is increased by forming the circular grooves 114e and 114f and the linear groove 114g at the time of working and forming.

  The first LED light source board 115 includes a ring-shaped wiring board 115a, and a plurality of LED element groups 115b arranged in a line on one surface side (floor side) of the wiring board 115a. It is mounted on the outer periphery of the plate 114. The LED element group 115b includes, for example, a daylight LED 115b1 that emits daylight light and a bulb LED 115b2 that emits light of bulb color, and each element is arranged alternately in the circumferential direction. I have. For example, the light bulb color LED 115b2 is arranged with two daylight LED 115b1 interposed therebetween. This makes it possible to emit light of three colors of light bulb color, light bulb color + daylight color, and daylight color. Further, by adding a dimming mechanism to the LED element group 115b, it is possible to emit finer color light. Will be possible.

  The wiring board 115a is formed, for example, by forming an insulating layer and a copper foil pattern on a substantially annular metal plate made of an aluminum alloy, or by forming a copper foil pattern on a flat plate of a resin having good thermal conductivity (for example, a polyimide resin). And a solder resist or the like.

Further, screw insertion holes 115c through which screws (not shown) are inserted when the first LED light source substrate 115 is fixed to the heat radiating plate 114 with screws are formed in the wiring board 115a at a plurality of positions at intervals in the circumferential direction. ing.

  In the present embodiment, by providing the main body base 111 and the heat radiating plate 114 configured as described above, the volume of the heat radiating space is increased (the amount of air in the heat radiating space is increased), and the power supply board 113 and the first LED light source are provided. The radiation efficiency of the substrate 115 can be improved. As a result, the luminous efficiency of the LED element group 115b can be increased.

  The LED cover 116 is formed in a ring shape so as to cover the entire first LED light source board 115. The LED cover 116 is formed in a film shape from a colorless and transparent synthetic resin (for example, PET: polyethylene terephthalate resin). This can prevent the user from touching the first LED light source substrate 115 when installing the LED lighting device 1B. That is, in the LED lighting device 1B of the present embodiment, since the user himself / herself attaches / detaches the light guide plate 131, the user does not touch the first LED light source substrate 115 when attaching / detaching the light guide plate 131.

  The LED cover 116 has a plurality of screw insertion holes 116a at positions corresponding to the screw insertion holes 115c. Although not shown, the LED cover 116 may be prevented from floating by a separately provided suppressing member.

  The reflection sheet 117 has a function of reflecting light emitted from the LED element group 115b to the ceiling side to the floor side, and is formed in a donut shape (annular shape) in plan view. The reflection sheet 117 is formed of a white resin sheet. In the present embodiment, the case where the reflection sheet 117 is provided has been described as an example. However, the present invention is not limited to this, and a configuration in which the heat sink 114 is coated with high reflection may be used.

  The light blocking member 118 has a function of preventing light of the LED element group 115b from leaking into the inside of the light guide plate 131, and is formed in a ring shape from, for example, ABS (Acrylonitrile Butadiene Styrene) resin. Further, the light shielding member 118 suppresses the outer peripheral edge 117 a of the reflection sheet 117.

  The security light cover 119 covers a second LED light source substrate 121 to be described later, and is formed in a ring shape. In addition, the security light cover 119 is formed of a material having light transmissivity, and a locking portion 119a for locking the security light cover 119 to the fixing portion 112a is formed on an inner peripheral edge portion.

  The second LED light source substrate 121 has a wiring board 121a, on which a warm-color LED element 121b used as a security light and a blue LED 121c emitting blue light are alternately arranged in the circumferential direction. It is arranged and configured. Further, the second LED light source substrate 121 is disposed radially inward (in the present embodiment, the innermost circumference) of the first LED light source substrate.

  The center cover 122 covers a mounting adapter (not shown) exposed at the center of the apparatus main body, and is formed of, for example, synthetic resin having flame retardancy (for example, PP: polypropylene resin). Further, the center cover 122 is formed in a disk shape and is detachably attached to the security light cover 119.

  The sensor unit 123 changes power supplied to the LED element group 115b in accordance with, for example, the brightness of the environment (space) in which the LED lighting device 1B is installed, and obtains a constant illuminance under the LED lighting device 1B. Provide a function to make it. Further, the sensor unit 123 detects the illuminance below the LED lighting device 1B. The sensor unit 123 is configured such that a sensor substrate (not shown) is housed in a sensor case 123a formed of ABS resin, polypropylene resin, or the like. I have.

  The light guide plate 131 has a function of guiding a light beam emitted from the plurality of LED element groups 115b to the floor side, and is located on the outermost side (floor side, outer surface side) of the LED lighting apparatus 1B and serves as a cover of the LED lighting apparatus 1B. Function. In this way, by arranging the light guide plate 131 on the outermost side (the floor side, the outer surface side), the performance of the LED element group 115b can be used to the maximum. Also, since no milky white cover is provided further outside the light guide plate 131, the LED lighting device 1B can be made thinner.

  The light guide plate 131 is integrally formed by injection molding or the like, for example, using a translucent and electrically insulating resin made of PMMA (polymethyl methacrylate resin). The material of the light guide plate 131 is not limited to PMMA, but may be any material having a light-transmitting property and an electrical insulating property, and may be another resin such as a polystyrene resin or a polycarbonate resin. However, the present invention is not limited to this, and may be glass or the like.

  Further, the light guide plate 131 is formed in a dish shape so that the concave surface faces the ceiling side, and a flange portion 131 a that is detachably held by the receiver 140 is formed on the outer periphery of the light guide plate 131. The flanges 131a are formed at three locations on the outer peripheral edge of the light guide plate 131.

  At the center of the surface of the light guide plate 131, a concave portion 131c having a circular shape in a plan view is formed. The concave portion 131c is a portion where a gate mark (resin filling mark) is formed when the light guide plate 131 is formed, and is a step for covering the gate mark remaining after injection molding with the light guide piece 133.

  The ring cover 132 is disposed so as to overlap the flange 131a of the light guide plate 131, and makes the collar 131a invisible from the floor side.

  The light guide piece 133 is formed of the same material as the light guide plate 131, and is formed in a small-diameter disk shape (coin shape). Further, the light guide piece 133 is fitted into a concave portion 131c formed in the light guide plate 131, and is fixed with an adhesive or the like. The light guide piece 133 has a groove 133a formed concentrically so that light is emitted similarly to the outer light guide plate 131.

  The receiving member 140 holds the light guide plate 131 in a detachable manner, and is formed of, for example, a synthetic resin such as POM (polyoxymethylene).

  FIG. 11 is a perspective sectional view of the LED lighting device according to the second embodiment. FIG. 11 shows a state in which the LED lighting device 1B is cut in half so as to pass through the center in the radial direction.

  As shown in FIG. 11, on the inner surface of the light guide plate 131, a plurality of grooves 131d are formed concentrically. By forming the groove 131d on the inner surface of the light guide plate 131 in this way, it is possible to prevent dust and the like from accumulating in the groove 131d, and to stably emit light.

  The groove 131d is formed entirely except for the recess 131c. Thereby, the light of the LED element group 115b can be diffused to the entire surface including the substantially central portion of the light guide plate 131. The interval s between the adjacent grooves 131d is formed so as to gradually decrease from the outside in the radial direction toward the center. As a result, the light can be uniformly emitted from the outer circumference to the inner circumference in the radial direction. Although not shown, each groove 131d is further textured. Thereby, light can be diffused over the entire surface of the light guide plate 131.

  FIG. 12 is an enlarged view of a portion A in FIG.

  As shown in FIG. 12, the light guide plate 131 is disposed to face the LED element group 115b, and the light is incident from the incident part 131i on which the light of the LED element group 115b (the daylight LED 115b1 and the light bulb LED 115b2) is incident. And an emission unit 131o that emits the emitted light from the whole including the central portion of the light guide plate 131.

  The incident part 131i is a part corresponding to the thickness of the light guide plate 131, and is formed in an annular shape along the arrangement of the LED element group 115b.

  The emission part 131o has a curved part 131o1 extending from the incident part 131i toward the floor, and a flat part 131o2 formed in a disk shape in the horizontal direction.

  When the light of the LED element group 115b is incident from the incident portion 131i, the light is guided inside the light guide plate 131, and the light is emitted from the emission portion 131o to the outside (floor side) of the light guide plate 131. Further, the light shielding member 118 prevents light incident on the incident portion 131i from leaking into the light guide plate 131.

  In the second embodiment, the daylight LED 115b1, the bulb LED 115b2, and the blue LED 121c can be controlled by the control unit 101 (see FIG. 5) similar to the first embodiment. Further, as described with reference to FIGS. 8 and 9, various modes can be set.

  That is, by adding the "blue LED addition mode" in which the blue LED 121c is additionally lit to the "all light mode" in which the daylight LED 115b1 and the bulb LED 115b2 are lit at the rated output, the radiation intensity at the wavelength of 470 nm to 480 nm is complemented. Can be easily read. In addition, in the brightness-up mode, which has 1.2 times the brightness of the full-light mode, the control of the blue LED 121c turns on and off by optimizing the current flowing to each of the daylight LED 115b1 and the bulb LED 115b2. It is possible to realize a simplified control circuit, a reduced number of circuit components, and a smaller power supply board while maintaining a function that makes it easy to see characters, etc. .

  In the second embodiment, the daylight LED 115b1 is arranged in a line in a ring, and is arranged radially inside (the innermost peripheral side) of the daylight LED 115b1 and the bulb LED 115b2. According to this, the first LED light source substrate 115 and the second LED light source substrate 121 can be divided into two substrates and can be configured with a minimum substrate area, and the substrate can be configured at a lower cost than when one substrate is arranged on the entire surface. it can.

  Note that the present invention is not limited to the above-described embodiment, and can be variously modified without departing from the gist of the present invention.

  Further, the shape of the LED lighting devices 1A and 1B is not limited to a round shape, but may be another shape such as a square shape such as a square or a polygonal shape.

1A, 1B LED lighting device (lighting device)
11, 111 Main body base 11a, 111a Adapter mounting hole 12, 112 Adapter receiving portion (insulating material)
13, 113 Power supply board 14, 114 Heat sink 15A, 15B LED light source board 15b LED element group 15b1 Daylight LED
15b2 Light bulb color LED
15b3 Blue LED
Reference Signs List 16 reflection sheet 17 LED cover 19 seed 31 light guide cover main body 131 light guide plate 131a collar 101 control unit 102 (changes drive current of daylight LED) light control circuit 103 (changes drive current of light bulb color LED) Circuit 104 Lighting circuit (turns on / off the blue LED) 115 First LED light source board 115b LED element group 115b1 Daylight LED
115b2 Light bulb color LED
116 LED cover 117 Reflective sheet 121 Second LED light source board 121c Blue LED
131 light guide plate 131i incident part 131o emission part

Claims (1)

A daylight LED that emits daylight,
A light bulb color LED emitting light of a light bulb color,
A blue LED that emits blue light,
A control unit that controls the daylight LED, the bulb LED and the blue LED,
The control unit controls the daylight LED and the bulb LED and the blue LED to be simultaneously turned on, and the daylight LED and the bulb LED continuously vary the current value individually. A lighting device, which controls only lighting and extinguishing.

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