JP2009266672A - Lighting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting device capable of performing rendering for advantaging an object itself by providing the object with light to be changed from moment to moment using an ultraviolet lamp and a visible light. <P>SOLUTION: Pattern data 25 includes fade-in means 26 for gradually shifting the illuminance of the ultraviolet lamp 11 or the visible light lamps 12 and 13 from dark illuminance to bright illuminance, and fade-out means 27 for gradually shifting the illuminance of the ultraviolet lamp 11 or the visible light lamps 12 and 13 from bright illuminance to dark illuminance. Thus, in the lighting device 1, the rendering of color to be provided to the object 5 can be enjoyed so that the object is emitted by the ultraviolet lamp 11 to appear white and clear, and clear white is gradually faded next time and the color of the visible lights 12 and 13 appears. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention is equipped with an ultraviolet lamp in a part of a lighting unit used for wall lighting that illuminates a wall surface in a room or lighting for a subject that is displayed on a display window, or lighting that illuminates a wall surface of an outdoor building, etc. The present invention relates to an illuminating device that produces a subject with its illumination.

  An illumination device using an ultraviolet lamp is used in various applications. For example, an ultraviolet lamp that emits ultraviolet light in a wavelength region of 315 nm to 400 nm and a visible light lamp that emits visible light are accommodated in one unit and light emission is performed. There is a lighting fixture that is configured to irradiate a subject partially coated with a paint having a function, and the subject having a light emitting function emits fluorescence by irradiating ultraviolet rays from an ultraviolet lamp, and other than having a light emitting function The part is irradiated with visible light from a visible light lamp and becomes brighter, and the brightness difference between the part having the light emitting function and the part other than the light emitting function is reduced, and a technique for improving the visibility is adopted (for example, Patent Document 1).

JP-A-10-331119 (paragraph [0017] to paragraph [0019], paragraph [0021] to paragraph [0023], FIG. 1)

Conventionally, ultraviolet lamps have been adopted as lighting for production. For example, a fluorescent paint that is not visible in the wavelength band of visible light and that emits light in the wavelength band of ultraviolet light is drawn on the wall surface of the room, and an ultraviolet lamp is irradiated when the room is darkened. There are things that are suddenly used to produce surprises when a picture drawn with fluorescent paint emerges.
However, in these effects, the subject changes because when the ultraviolet lamp is turned on and the visible light is turned off, a picture drawn on the wall surface (subject) appears, or vice versa, the ultraviolet lamp is turned off and the visible light is turned off. There were only two types of changes in whether the wall surface appeared when the was turned on, and the usage of the production was limited. The elements of these effects are mainly pictures drawn with a fluorescent paint having a light emitting function, and the wall surface (subject) itself is not an object of attention.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an illumination device that uses an ultraviolet lamp and a visible light lamp, can give an ever-changing light to a subject, and can produce an effect to enhance the subject itself. .

  In order to solve this problem, the present invention described in claim 1 is based on ultraviolet lamps (ultraviolet lamps 11 such as LEDs, EEFLs, fluorescent tubes, and light bulbs) that emit ultraviolet rays (BLA) and visible rays (COO · CYY). And may be any one of visible light lamps (visible light lamps 12 and 13) that emit chromatic colors (orange, yellow, such as blue, green, purple, red, pink, fluorescent lamp color, etc.), Other visible light lamps, for example, LEDs, EEFLs, fluorescent tubes, light bulbs, etc. are housed in one unit, and are configured to irradiate subjects (5, 6, such as toys, walls, clothes, bags, etc.) An illumination unit (illumination unit 10) and a control unit (control unit 40) connected to the illumination unit (illumination unit 10) and controlling the illuminance of the ultraviolet lamp and the visible light lamp And the control unit determines the illuminance of each lamp (the ultraviolet lamp 11, the visible light lamps 12 and 13, and the visible light lamp may be any one). Pattern data (pattern data 25) in which patterns to be controlled with time are stored, and each of the lamps (ultraviolet lamp 11, visible light lamps 12.13, visible light lamps based on the pattern data (pattern data 25)) A control controller (control controller 20) for controlling the illuminance of the lamp (which may be one), and the pattern data (pattern data 25) includes the lamps (ultraviolet lamp 11 and visible light lamps 12 and 13, Fade-in that gradually shifts the illuminance of the visible light lamp (which may be any one) from dark to bright The illuminance of the means (fade-in means 26) and each of the lamps (the ultraviolet lamp 11, the visible light lamps 12 and 13, or any one of the visible light lamps may be any one) is gradually shifted from bright illuminance to dark illuminance. And a fade-out means (fade-out means 27).

With the above configuration, the illumination device can change the illuminance of the light applied to the subject from time to time by using an ultraviolet lamp or visible light lamp, so that the subject emits light due to the radiation of the ultraviolet lamp and looks bright and white. However, this time it gradually fades and the light color of the visible light lamp appears, so you can enjoy various color effects on the subject.
The present embodiment can be realized even if any one of the visible light lamps is used, but when there are a plurality of visible light lamps, it is possible to radiate a multi-colored color, so that it is possible to produce various effects.

In order to solve this problem, in the present invention according to claim 2, the pattern data (pattern data 25) includes one of each lamp (the ultraviolet lamp 11, the visible light lamps 12 and 13, and the visible light lamp). When the maximum illuminance at the rated power of 100% may be set to 100%, the ultraviolet ray lamp (ultraviolet lamp 11, for example, LED, EEFL, fluorescent tube, light bulb) has the illuminance of 100%. The lamp (which may be any one of the visible light lamps 12 and 13; other visible light lamps, for example, LEDs, EEFLs, fluorescent tubes, light bulbs) is provided with a pattern for lighting at 100% illuminance. Features.
With the above configuration, when the ultraviolet lamp has an illuminance of 100%, the illuminating device has a visible light lamp having an illuminance of 100%. Therefore, the light of the visible light lamp is emitted to the subject, and the color of the light of the visible light lamp The subject is mixed with the light emitted from the ultraviolet lamp and looks white and vivid. This is because the illuminance of the ultraviolet lamp and the visible light lamp changes every moment, so that the subject can be seen more clearly.
The present embodiment can be realized even if any one of the visible light lamps is used, but when there are a plurality of visible light lamps, it is possible to radiate a multi-colored color, so that it is possible to produce various effects.

In order to solve this problem, according to the present invention, the illumination unit (illumination unit 10) has different chromatic colors (orange, yellow, for example, blue, green, purple, red, pink, fluorescent lamp color, etc.). ) Visible light lamps (visible light lamps 12 and 13, for example, LEDs, EEFLs, fluorescent tubes, light bulbs) are provided, and the pattern data (pattern data 25) includes each lamp (ultraviolet lamp 11 and visible light lamp). 12.13) When the maximum illuminance at the rated power is 100%, at least one of the ultraviolet lamps (ultraviolet lamps 11, for example, LEDs, EEFLs, fluorescent tubes, light bulbs) has an illuminance of 100%. One of the visible light lamps (visible light lamps 12 and 13 such as LEDs, EEFLs, fluorescent tubes and light bulbs) is provided with a pattern for lighting at 100% illuminance. And features.
With the above configuration, when the ultraviolet lamp has an illuminance of 100%, the illuminating device has a visible light lamp having an illuminance of 100%. Therefore, the light of the visible light lamp is emitted to the subject, and the color of the light of the visible light lamp The subject emits light from the ultraviolet lamp and looks vivid, so that it can stand out. This is because the illuminance of each lamp changes from moment to moment, so that the subject looks more prominent.

  In order to solve this problem, the present invention described in claim 4 uses an ultraviolet lamp (ultraviolet lamp 11 such as an LED / EEFL / fluorescent tube or a light bulb) that emits ultraviolet light (BLA) and visible light (COO / CYY). It may be any one of visible light lamps (visible light lamps 12 and 13) that emit chromatic colors (orange, yellow, for example, blue, green, purple, red, pink, fluorescent lamp color, etc.). For other visible light lamps, for example, LEDs, EEFLs, fluorescent tubes) are housed in a single unit, and illumination is configured to illuminate a subject (5, 6, such as toys, walls, clothes, bags, etc.) A unit (illumination unit 10), and the ultraviolet lamp (ultraviolet lamp 11, such as LED / EEFL / fluorescent tube, light bulb) connected to the illumination unit (illumination unit 10) and A control unit (control unit 40) for controlling the illuminance of the visible light lamp (which may be any one of the visible light lamps 12 and 13; for other visible light lamps, for example, LEDs, EEFLs, fluorescent tubes); The control unit (control unit 40) includes an input unit (input unit 33) for inputting a commercial AC power source (commercial AC power source 7, for example, AC100V, AC200V). , A power adjustment unit (power adjustment unit 35) that adjusts the current or voltage of the power source input from the input unit (input unit 33), and each lamp (ultraviolet lamp 11, visible light lamps 12 and 13, and visible light lamp 12). 13 is provided corresponding to any one of them, and is connected to the power adjustment unit (power adjustment unit 35) and connected to the lamps (ultraviolet lamp 11 and visible light lamp). 2 and 13 and the visible light lamps 12 and 13 may be any one. Other visible light lamps include, for example, LEDs, EEFLs, and fluorescent tubes. An operation switch 32) and an output unit (output unit 34) that outputs electric power adjusted by the operation switch (operation switch 32) to the illumination unit (illumination unit 10).

With the above configuration, the lighting device can emit light with a desired illuminance of 0 to 100% of the ultraviolet lamp, and can emit light with a desired illuminance of 0 to 100% of the visible light lamp. As a result, it is possible to enjoy various color changes reflected in the subject.
The present embodiment can be realized even if any one of the visible light lamps is used, but when there are a plurality of visible light lamps, it is possible to radiate a multi-colored color, so that it is possible to produce various effects.

  According to the configuration of the present invention, it is possible to provide an effect for giving the subject a light that changes every moment to the subject and making the subject stand out.

This embodiment will be described below with reference to FIGS.
FIG. 1 is a perspective view showing an outline of a show window case equipped with a lighting unit in the present embodiment. FIG. 2 is a cross-sectional view as seen from the side showing the outline of the show window case equipped with the illumination unit in the present embodiment. FIG. 3 is a perspective view showing the illumination unit in the present embodiment.

  1 and 2 show an outline of the show window case 3 on which the lighting unit 10 is mounted. The show window case 3 is formed in a box shape with a part opened, and a space in which the subjects 5 and 6 can be placed is provided in the opened interior. In addition, an illumination unit 10 that emits light toward the subjects 5 and 6 is built in the upper interior of the show window case 3 at a distance of 20 cm from the tip of the subject 5.

  In the present embodiment, the subject 5 shows artificial flowers and the subject 6 shows wrinkles. In particular, among fabric products (clothes, banners, artificial flowers, etc.), white fabric products absorb ultraviolet rays (wavelength around 380 nm) to show a bright white color, and visible blue light (wavelength around 440 nm) is visible. A fluorescent whitening agent (fluorescent paint) is used in the production stage as a dye that is released instead of the above. For this reason, when ultraviolet rays are emitted to a subject using these fabric products, white appears brightly. And in this Embodiment, the artificial flower 5 in which the fluorescent whitening agent was used is mounted, and the illumination unit 10 is installed in the position 20 cm away from the front-end | tip of the artificial flower 5. FIG.

The lighting unit 10 will be described with reference to FIGS. In the illumination unit 10, a transformer (not shown), an ultraviolet lamp 11, and visible light lamps 12 and 13 are built in a box-shaped housing 15. The ultraviolet lamp 11 and the visible light lamps 12 and 13 are sandwiched and attached on a plate-like base plate 18 by gripping tools 16 provided at two locations. A transparent cover 14 that covers the lamps 11, 12, and 13 is fitted and fixed at the upper end of the housing 15 above the lamps 112 and 13.
A wiring hole 17 into which wiring from a transformer (not shown) and output lines from a controller 20 and a control BOX 30 described later are inserted is provided on the side surface of the housing 15. A mounting piece 19 projecting sideways is provided at the lower end of the housing 15. The mounting piece 19 is attached and fixed to the show window case 3 and the wall surface with screws or the like.

Each of the ultraviolet lamp 11 and the visible light lamps 12 and 13 is formed of a glass tube whose both ends are bent, and flat electrodes are sealed at both ends of the glass tube. As the ultraviolet lamp 11 and the visible light lamps 12 and 13, argon gas was used as the sealing gas, and a lamp utilizing the light emission phenomenon of the positive column observed during glow discharge was used.
In the ultraviolet lamp 11, when a fluorescent material is applied to the inner wall of the glass tube and light is emitted at around 13 W, which is the maximum value of the rated power of the lamp, the peak wavelength for emitting ultraviolet light from the glass tube is 368 nm.
The visible light lamp 12 is a lamp that emits orange (COO) light by applying a fluorescent material to the inner wall of a glass tube. When the visible light lamp 12 emits light at 13.2 W which is the maximum value of the rated power of the lamp, the chromaticity x defined by the CIE 1931 standard color system defined by the International Lighting Commission in 1931 is 0. 592 and emits a color having a value of chromaticity y of 0.391.
The visible light lamp 13 is a lamp that emits yellow (CYY) light by applying a fluorescent material to the inner wall of the glass tube. When the visible light lamp 12 emits light at 13.6 W which is the maximum value of the rated power of the lamp, the chromaticity x defined by the CIE 1931 standard color system is 0.490 and the chromaticity y is 0.00. It emits light having a value of 495.

Based on FIG. 4, the structure of the illuminating device 1 in Example 1 is demonstrated based on a block diagram. FIG. 4 is a block diagram showing the illumination device 1 according to the first embodiment.
The lighting device 1 includes the lighting unit 10 and the control unit 40 described above. In this embodiment, the lighting unit 10 is housed in the show window case 3, and the lighting unit 10 is directed toward the subject 5 from the lamps 11, 12, and 13 with ultraviolet rays (BLA), visible light (CYY), and visible light (COO). Is radiating.

The control unit 40 includes a control controller 20, a control BOX 30, a converter 36, and a DC power source 37, and is connected to the lighting unit 10 and the commercial AC power source 7 (AC 100V).
The controller 20 inputs AC power from the commercial AC power source 7 to the input unit 33. The controller 20 includes a power adjustment unit 35 that adjusts the power by controlling the current or voltage of the input commercial power supply. The power adjusted by the power adjustment unit 35 is output to the illumination unit 10 via the output unit 34.
The controller 20 can connect a plurality of lighting units 10. The controller 20 controls the power adjustment unit 35 based on pattern data 25 described later by the built-in CPU 21. The power adjustment unit 35 controls the illuminance by controlling the timing and power amount for outputting the power of the plurality of lighting units 10.
The CPU 21 incorporates a rewritable EEPROM 24 and RAM 23. The EEPROM 24 stores a plurality of pattern data 25 for turning on the plurality of illumination units 10 in a predetermined data storage area 24. In the pattern data 25, fade-in means 26 and fade-out means 27 are provided. The fade-in means 26 is pattern data 25 for gradually shifting the illuminance of the lamps 11, 12, and 13 from dark illuminance to bright illuminance, and the fade-out means 27 changes the illuminance of the lamps 11, 12, and 13 to bright illuminance. Pattern data 25 that gradually shift from low to dark illuminance.

Next, the control BOX 30 is provided with a main switch 31 and operation switches 32 corresponding to the lamps 11, 12, and 13. The main switch 31 is a switch for turning ON / OFF the power supply of the control BOX 30, and the operation switch 32 is a slide type switch.
An A / D converter 36 is connected between the control controller 20 and the control BOX 30.
The A / D converter 36 converts the analog value input from the control BOX 30 into a digital signal and transmits the data to the control controller 20. The A / D converter 36 is driven by a DC power source 37.
(Operation of control BOX)

When the control box 30 turns on the main switch, an ON signal flows through the A / D converter 36. Based on the input of the ON signal, the control controller 20 invalidates the control by the pattern data 25 and determines that the input from the control BOX 30 is valid and performs switching (switching means). Then, when the operation switch 32 is operated, the control BOX 30 gives a signal for controlling the electric energy to the controller 20 linearly or stepwise in accordance with the slide amount. The controller 20 adjusts the amount of electric power by adjusting the current or voltage of the input commercial power supply in accordance with the signal input from the control BOX 30 and outputs it to the lighting unit 10. In this way, the controller 20 can adjust the illuminance of the lamps 11, 12, and 13 in accordance with the operation of the operation switch 32 of the control BOX 30.
(Production operation of the lighting device)

  Based on FIG. 5 thru | or FIG. 7, the operation | movement of the production of the light which the illuminating device 1 radiates | emits to the to-be-photographed objects 5 * 6 is demonstrated. FIG. 5 is a timing chart A showing the relationship between the illuminance of each of the lamps 11, 12, and 13 controlled by the pattern data 1 stored in the controller 30 in the present embodiment in Example 1 and time. FIG. 6 is a conceptual diagram showing the illuminance of each of the lamps 11, 12, and 13 controlled by the data 1 stored in the controller 30 in the present embodiment in Example 1 for each time. FIG. 7 is a timing chart B showing the relationship between the illuminance of each of the lamps 11, 12, and 13 controlled by the pattern data 2 stored in the controller 30 according to the present embodiment in Example 1 and time.

  In the pattern data 1 shown in FIG. 5, the horizontal axis represents time, and the vertical axis represents the illuminance of each lamp 11, 12, 13. The illuminance of each of the lamps 11, 12, and 13 is 100% when radiating around 13 W, which is the maximum value of the rated power. The time axis is about 6 seconds from A to G, and time intervals of 1 second are described from A to G evenly.

  The ultraviolet lamp 11 has an illuminance of 100% at time A and emits ultraviolet rays (BLA). Thereafter, the ultraviolet lamp 11 gradually decreases the illuminance linearly. At time D, the illuminance shows 0% and no ultraviolet (BLA) is emitted. Thereafter, the ultraviolet lamp 11 gradually increases the illuminance linearly from time D and emits ultraviolet light (BLA). At time G, the illuminance indicates 100% and emits ultraviolet light (BLA). The process of time A → time B → time C → time D shows one of the fade-out means 27 for gradually shifting the illuminance of the ultraviolet lamp 11 from bright illuminance to dark illuminance. The process of time D → time E → time F → time G shows one of the fade-in means 26 of the ultraviolet lamp 11 that gradually changes the illuminance of the ultraviolet lamp 11 from dark illuminance to bright illuminance.

  The visible light lamp 12 has an illuminance of 100% at time A and emits orange visible light (COO). Thereafter, the visible light lamp 12 gradually decreases the illuminance linearly. At time G, the illuminance shows 0%, and no orange visible light (COO) is emitted. The process of time A → time B → time C → time D → time E → time F → time G shows one of the fade-out 27 means for gradually shifting the illuminance of the visible light lamp 12 from bright illuminance to dark illuminance. Yes.

The visible light lamp 13 has an illuminance of 0% at time A, and no yellow visible light (CYY) is emitted. Thereafter, the visible light lamp 13 gradually increases the illuminance linearly. At time G, the illuminance shows 100% and emits orange visible light (COO). The process of time A → time B → time C → time D → time E → time F → time G shows one of the fade-in means 26 for gradually shifting the illuminance of the visible light lamp 13 from dark illuminance to bright illuminance. ing.
Thus, the light emitted from the illumination unit 10 changes with time, and the subjects 5 and 6 are emphasized by the light emitted by the illumination unit 10. This will be described with reference to FIG.

  When the light emitted from the illumination unit 10 is time A, the ultraviolet lamp 11 emits ultraviolet light (BLA) with an illuminance of 100%, and the visible light lamp 12 has an orange visible light (COO) with an illuminance of 100%. The visible light lamp 13 does not emit. Therefore, orange visible light (COO) and ultraviolet rays (BLA) are radiated, the entire show window case 3 is reflected in orange, and the subject 5 to which the fluorescent paint that emits blue is applied is bluish white and vivid. appear.

Thereafter, at time B, the ultraviolet lamp 11 emits ultraviolet light (BLA) with an illuminance of about 66%, and the visible light lamp 12 emits orange visible light (COO) with an illuminance of about 84%. The lamp 13 emits yellow visible light (CYY) with an illuminance of about 16%. The entire display window case 3 is reflected in orange, the subject 5 is slightly bluish, and the white subject 5 appears orange.
At time C, the ultraviolet lamp 11 emits ultraviolet light at an illuminance of about 33%, the visible light lamp 12 emits orange visible light (COO) at an illuminance of about 66%, and the visible light lamp 13 is about 32. It emits yellow visible light (CYY) at% illuminance. For this reason, the entire show window case 3 is reflected in orange, the subject 5 appears to be pale, and the white subject 5 appears to be orange with a little yellow.

  At time D, the ultraviolet lamp 11 does not emit ultraviolet light (BLA). The visible light lamp 12 emits orange visible light (COO) with an illuminance of about 50%, and the visible light lamp 13 emits yellow visible light (CYY) with an illuminance of about 50%. Therefore, the entire show window case 3 appears in a yellowish orange color, and the white subject 5 appears in a yellowish orange color.

  At time E, the ultraviolet lamp 11 emits ultraviolet rays (BLA) with an illuminance of about 33%, the visible light lamp 12 emits orange visible light (COO) with an illuminance of about 32%, and the visible light lamp 13. Emits yellow visible light (CYY) with an illuminance of about 66%. Therefore, the entire show window case 3 is reflected in yellow, and the subject 5 has a slightly pale color. The white subject 5 looks yellow with a little orange.

  At time F, the ultraviolet lamp 11 emits ultraviolet light (BLA) with an illuminance of about 66%, the visible light lamp 12 emits orange visible light (COO) with an illuminance of about 16%, and the visible light lamp 13. Emits yellow visible light (CYY) at an illuminance of about 84%. For this reason, the entire show window case 3 is reflected in yellow, and the subject 5 has a pale color. The white subject 5 appears yellow.

  At time G, the ultraviolet lamp 11 emits ultraviolet light (BLA) with an illuminance of 100%, the visible light lamp 12 does not radiate, and the visible light lamp 13 emits yellow visible light (CYY) with an illuminance of 100%. To do. For this reason, orange visible light (COO) and ultraviolet light (BLA) are emitted, the entire display window case 3 appears yellow, and the subject 5 to which the fluorescent paint emitting blue light is applied appears blue and white and looks vivid. .

Next, pattern data 2 shown in FIG. 7 will be described as another effect pattern.
The ultraviolet lamp 11 has an illuminance of 100% at time A and emits ultraviolet rays (BLA). Thereafter, the ultraviolet lamp 11 gradually decreases the illuminance linearly and when the illuminance is set to 0% at time B, the illuminance is gradually increased linearly to increase the illuminance to 100% at time C. The ultraviolet lamp 11 repeats this series of operations.
The visible light lamp 12 has an illuminance of 100% at time A and emits orange visible light (COO). Thereafter, the visible light lamp 12 gradually decreases the illuminance linearly and when the illuminance is reduced to 0% at time C, the illuminance is gradually increased linearly to increase the illuminance to 100% at time D. The visible light lamp 12 repeats this series of operations.
The visible light lamp 13 does not emit light at time A. Thereafter, the visible light lamp 13 gradually increases the illuminance linearly, and when the illuminance is set to 100% at time C, the illuminance is gradually decreased linearly, and the illuminance is set to 0% at time D. The visible light lamp 12 repeats this series of operations.

Pattern data 2 indicates that at time A, C, and G, the ultraviolet lamp 11 emits ultraviolet light (BLA) with 100% illuminance, and the visible light lamp 12 or the visible light lamp 13 is orange with 100% illuminance. Visible light (COO) or yellow visible light (CYY) is emitted.
In the pattern data 2, the ultraviolet lamp 11 is not emitted at times B, D, and F, but the visible light lamp 12 or the visible light lamp 13 is orange visible light (COO) or yellow visible light at 100% illuminance. A light beam (CYY) is emitted.

In particular, the emission color of the fluorescent paint of the subjects 5 and 6 and the color of the light emitted from the visible light lamps 12 and 13 are ultraviolet rays when the hue difference determined based on the Munsell hue ring is in a complementary color relationship of 10 to 11. When the lamp 11 emits ultraviolet light at 100% illuminance and one or both of the visible light lamps 12 and 13 emit at 100% illuminance, the surroundings of the objects 5 and 6 are visible light lamps 12 and 13. Illuminated by the radiation and the subjects 5 and 6 themselves are also illuminated, so that the subjects 5 and 6 look more vivid.
For example, in this embodiment, if the subject 5 is coated with a fluorescent paint that emits blue light, the visible light lamp 13 has an orange visible light (COO) or yellow visible light with an illuminance of 100%. (CYY) is emitted. In such a complementary color relationship, the subjects 5 and 6 are illuminated with orange and yellow, and the subjects 5 and 6 themselves are illuminated with orange and yellow, so the subjects 5 and 6 are blue due to ultraviolet rays. It emits light and looks clearer.

  Example 2 will be described with reference to FIG. FIG. 8 is a block diagram showing the lighting device 1 according to the second embodiment. The lighting device 1 includes the lighting unit 10 and the control unit 40 described above. In this embodiment, the lighting unit 10 is housed in the show window case 3, and the lighting unit 10 is directed toward the subject 5 from the lamps 11, 12, and 13 with ultraviolet rays (BLA), visible light (CYY), and visible light (COO). Is radiating.

As for the control part 40, control BOX30 is connected to the illumination unit 10 and the commercial alternating current power supply 7 (AC100V).
The control BOX 30 includes an input unit 33, an output unit 34, and a power adjustment unit 35. The input unit 33 inputs AC power from the commercial AC power source 7, and the output unit 34 outputs the power adjusted by the power adjusting unit 35 to the lighting unit 10. The power adjustment unit 35 includes a main switch 31 and operation switches 32 corresponding to the lamps 11, 12, and 13. The main switch 31 is a switch for turning ON / OFF the power supply to the lighting unit 10, and the operation switch 32 is a slide type switch.
(Operation of control BOX)

When the main switch is turned on, the control BOX 30 supplies the commercial power source input to the input unit 33 to the power adjustment unit 35. The power adjustment unit 35 adjusts the power by controlling the current or voltage of the input commercial power source according to the slide amount of the operation switch 32, and adjusts the power to the lighting unit 10 via the output unit 34. Is output. The control BOX 30 adjusts the illuminance of the lamps 11, 12, and 13 in accordance with the operation of the operation switch 32.
Further, by operating the operation switch 32, the illuminance of each of the lamps 11, 12, and 13 is gradually changed from the dark illuminance to the bright illuminance. The fade-out means 27 for gradually shifting to illuminance can be manually operated at desired time intervals.
(Effects grasped from this embodiment)

(1) In this embodiment, the ultraviolet lamp 11 that emits ultraviolet light (BLA) and the visible light lamps 12 and 13 that emit visible light and emit chromatic colors are housed in one unit, and the substance has a light emitting function. An illumination unit 10 configured to irradiate a subject 5 or 6 containing (for example, a fluorescent paint, a phosphorescent paint, or a fluorescent brightening agent), and an ultraviolet lamp 11 and a visible light lamp 12 or 13 connected to the illumination unit 10. The illumination device 1 includes a control unit 40 that controls the illuminance of the light, and the control unit 40 stores pattern data 25 in which a pattern for controlling the illuminance of the visible light lamps 12 and 13 with time is stored, and pattern data 25, and a controller 20 for controlling the illuminance of each of the lamps 11, 12, and 13 is provided. Fade-in means 26 for gradually shifting the illuminance of visible light lamps 12 and 13 from dark illuminance to bright illuminance, and fade-out means for gradually shifting the illuminance of ultraviolet lamp 11 or visible light lamps 12 and 13 from bright illuminance to dark illuminance. 27.
With the above configuration, the illuminating device 1 can change the illuminance of the light applied to the subjects 5 and 6 by the ultraviolet lamp 11 and the visible light lamps 12 and 13 every moment, so that the subjects 5 and 6 emit light by the ultraviolet lamp 11. You can enjoy a variety of color effects on subjects 5 and 6, such as the appearance of white and vivid, or the faint white gradually fading and the orange or yellow of visible light lamps 12 and 13 appearing gradually. be able to.
Note that this effect can be achieved even with a single visible light lamp, but if there are a plurality of visible light lamps, light can be emitted in multiple colors and various effects can be produced.

(2) In the present embodiment, the illumination unit 10 is configured such that the pattern data 25 sets the ultraviolet lamp 11 to 100% illuminance when the maximum illuminance at the rated power of each lamp 11, 12, 13 is 100%. At this time, the visible light lamps 12 and 13 are provided with a pattern for lighting with 100% illuminance.
With the above configuration, the illumination device 1 has the visible light lamp 12 or the visible light lamp 13 at 100% illuminance when the ultraviolet lamp 11 is set to 100% illuminance. Since the subjects 5 and 6 emit light and appear white and vivid while radiating to 5 and 6, the subjects 5 and 6 can be highlighted. This is because the illuminance of each of the lamps 11, 12, and 13 changes from moment to moment, so that the subjects 5 and 6 are even more prominent. Note that this effect can be achieved even with a single visible light lamp, but if there are a plurality of visible light lamps, light can be emitted in multiple colors and various effects can be produced.

(3) In the present embodiment, the illumination unit 10 is provided with at least two visible light lamps 12 and 13 having different chromatic colors, and the pattern data 25 indicates the maximum illuminance at the rated power of each lamp 11, 12, and 13. When the ultraviolet lamp 11 is set to 100% illuminance at 100%, at least one of the visible light lamps 12 and 13 is lit with 100% illuminance.
With the above configuration, the illumination device 1 has the visible light lamp 12 or the visible light lamp 13 with 100% illuminance when the ultraviolet lamp 11 is set to 100% illuminance. Since the subjects 5 and 6 emit light and appear white and vivid while radiating to 5 and 6, the subjects 5 and 6 can be highlighted. This is because the illuminance of each lamp 11, 12, and 13 changes from moment to moment, so that the subjects 5 and 6 are more prominently reflected.

(4) In the present embodiment, the control unit 40 includes a main switch 31 connected to the controller 20, an operation switch 32 that can operate illuminance corresponding to at least each of the lamps 11, 12, and 13, and pattern data Switching means for disabling the control at 25 and enabling the operation of the operation switch 32.
With the above configuration, the lighting device 1 can easily switch the operation for enabling the operation switch 32 just by turning on the main switch 31, so that the operation is simple.

(5) In the present embodiment, the illumination unit 10 emits chromatic light in which the hue of the emission color and the chromatic hue to be emitted when the subject 5 or 6 emits light by the ultraviolet lamp 11 are complementary. It is the structure provided with the visible light lamp which can.
With the above-described configuration, the illumination device 1 uses the visible light lamp 11 or the visible light lamp 12 that emits light of a color complementary to the emission color of the subject with the fluorescent paint, coupled with the illuminance change from moment to moment.・ 6 can be highlighted more clearly.
In the above configuration, even if there is only one visible light lamp, this effect can be obtained. However, if there are a plurality of visible light lamps, a plurality of colors can be emitted and various effects can be produced. By using visible light lamps 11 and 12 as visible light lamps as in the present embodiment, two colors can be expressed, and various effects can be produced.

(6) In the present embodiment, when the ultraviolet lamp 11 is not emitted from the illumination unit 10, the visible light lamp 12 or the visible light lamp 13 has an orange visible light (COO) or yellow visible light with an illuminance of 100%. The pattern data 25 is provided with a pattern that emits light (CYY).
With the above configuration, the illumination device 1 can enjoy various color changes reflected in the subjects 5 and 6 because the illuminance of the visible light lamp 12 or the visible light lamp 13 changes even when the ultraviolet lamp 11 is not emitted. Is possible.

(7) In the present embodiment, the illumination unit 10 is configured such that the visible light lamp 12 and the visible light lamp 13 are orange visible light (COO) or illuminance of 0 to 100% even when the ultraviolet lamp 11 is not emitted. The pattern data 25 includes a pattern emitting yellow visible light (CYY) with an illuminance of 0 to 100%.
With the above configuration, the illumination device 1 can enjoy various color changes reflected in the subjects 5 and 6 because the illuminance of the visible light lamp 12 or the visible light lamp 13 changes even when the ultraviolet lamp 11 is not emitted. Is possible.

(8) In the present embodiment, the ultraviolet lamp 11 that emits ultraviolet rays and the visible light lamps 12 and 13 that emit visible light and chromatic colors are housed in one unit, and a paint having a light emitting function is applied. An illumination device 1 comprising an illumination unit 10 configured to irradiate a subject, and a control unit 40 connected to the illumination unit 10 and controlling the illuminance of the ultraviolet lamp 11 and visible light lamps 12 and 13, The control unit 40 is provided corresponding to each of the lamps 11, 12, and 13, an input unit 33 that inputs commercial AC power, a power adjustment unit 35 that adjusts the current or voltage of the power input from the input unit, and the lamps 11, 12, and 13. The operation switch 32 connected to the power adjustment unit 35 and capable of adjusting the illuminance of each of the lamps 11, 12, and 13, and the electric power adjusted by the operation switch 32 are illuminated An output unit 34 for outputting the knit 10, a configuration in which a.
With the above configuration, the lighting device 1 can emit light with a desired illuminance of 0 to 100% of the ultraviolet lamp 11 and light with a desired illuminance of 0 to 100% of the visible light lamps 12 and 13. Therefore, it is possible to enjoy various color changes reflected in the subjects 5 and 6.
In the above configuration, even if there is only one visible light lamp, this effect can be obtained. However, if there are a plurality of visible light lamps, a plurality of colors can be emitted and various effects can be produced. By using visible light lamps 11 and 12 as visible light lamps as in the present embodiment, two colors can be expressed, and various effects can be produced.

(9) In the present embodiment, the lighting device 1 operates the operation switch 32 that can adjust the illuminance provided corresponding to each of the lamps 11, 12, and 13, so that the fade-in means 26 and Ford Since the time interval of the out means 27 can be freely changed and operated, it is possible to enjoy various color changes reflected in the subjects 5 and 6.
(Other technical ideas considered in this embodiment)

The illumination unit has a hue difference of 10 to 11 in which a difference between a hue of a light emission color when the subject is emitted by the ultraviolet lamp and a hue of a chromatic color emitted from a visible light lamp is determined based on at least a Munsell hue ring. The illumination device according to any one of claims 1 to 3, further comprising a visible light lamp capable of emitting chromatic color light.
With the above-described configuration, the lighting device 1 uses the visible light lamps 11 and 12 that emit light of a color complementary to the color emitted by the fluorescent paint of the subject to illuminate the subjects 5 and 6 in combination with momentary changes in illuminance. It can make it appear more vividly.
(Examples of changes to other embodiments)

The example which changed embodiment described above into other embodiment is shown below.
In the above embodiment, the peak wavelength of light emitted from the ultraviolet lamp 11 has been described as 368 nm. However, as long as the long wavelength ultraviolet light is used in the range of 320 nm to 400 nm, it is safe without harm to the human body. Can be used for
In the present embodiment, the visible light lamps 12 and 13 are described as neon tube lamps, but may be LEDs, fluorescent tube lamps, EEFL lamps, or light bulbs. In particular, an LED can emit multiple colors with a single module, and thus can be configured compactly.
In the above embodiment, the subjects 5 and 6 have been described with artificial flowers and bags. However, objects, monuments, statues, signboards, evacuations, etc. that can be displayed on display window cases such as cars, bicycles, bags, clothes, and toys as subjects. Guide signboards, indoor wall surfaces, and outdoor wall surfaces are possible.
In the above-described embodiment, the direct illumination in which the light from the illumination unit 10 is directly illuminated on the subject 5 or 6 has been described. However, the light from the illumination unit 10 is reflected on the wall surface or the like and then reflected on the subject 5 or 6. Indirect illumination that radiates may be used.
In addition to the above-described embodiment, various fluorescent paints may be employed. The fluorescent paint emits a fluorescent color under visible light, and emits a vivid color under ultraviolet light. There are colors, cream, lemon, pink and blue. In addition, for example, it is substantially colorless or white under visible light, and emits different colors under ultraviolet light. As an aqueous fluorescent pigment, orange, orange yellow, magenta, lemon, red orange, Sully's, white, blue, There are paints such as green and red.
In the above-described embodiment, the ultraviolet lamp 11 and the ultraviolet lamps 12 and 13 are made by applying a fluorescent material to the inner wall of the glass tube, but the tube may be colored to emit light.

In the above embodiment, the operation switch 32 has been described as a slide type switch, but may be a volume type.
In the above-described embodiment, the illuminance is 100% when the rated power of each of the lamps 11, 12, and 13 is 13 W, but is not particularly limited, and can be changed according to the characteristics of each lamp. What is necessary is just to make the illumination intensity which can be output maximum with rated power be 100%, and it should just be determined so that the light extinction state may be 0% on the basis of 100%.
In the above embodiment, each pattern data 25 is linearly controlled for each time as shown in FIG. 5 and FIG. 7. However, the pattern data 25 is a curve or stepwise control according to the characteristics of each lamp. It may be.
In the above embodiment, the pattern data 1 and 2 always indicate patterns in which the visible light lamps 12 and 13 emit light, but may include patterns that only emit light from the ultraviolet lamp 11. .
In the above-described embodiment, the objects 5 and 6 are objects to which a fluorescent material is applied, but may be an object formed by kneading a fluorescent material from the beginning. For example, there are decorations, toys and figurines manufactured by molding plastics and rubbers containing fluorescent materials.

  The lighting device can be used not only for the display window case used in the lighting device according to the present embodiment, but also for a ceiling surface or a floor surface of a show window seen at a street corner or an installed signboard.

It is the perspective view showing the outline | summary of the show window case carrying the illumination unit in this embodiment. It is sectional drawing seen from the side surface showing the outline | summary of the show window case carrying the illumination unit in this embodiment. It is the perspective view showing the lighting unit in this embodiment. 1 is a block diagram showing a lighting device in Embodiment 1. FIG. It is the figure of the timing chart A showing the relationship between the illumination intensity of each lamp | ramp controlled by the pattern data 1 memorize | stored in the controller in this embodiment in Example 1, and time. It is the conceptual diagram which showed the illumination intensity of each lamp | ramp controlled by the pattern data 1 memorize | stored in the controller in Example 1 in Example 1 for every time. It is the figure of the timing chart B showing the relationship between the illumination intensity of each lamp | ramp controlled by the pattern data 2 memorize | stored in the controller in this embodiment in Example 1, and time. It is the block diagram showing the illuminating device in Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Illuminating device, 2 ... Control part, 3 ... Show window case,
5.6 ... Subject, 7 ... AC power supply,
10 ... Lighting unit, 11 ... UV lamp,
12 ... Visible light lamp, 13 ... Visible light lamp,
14 ... Cover, 15 ... Housing, 16 ... Holder, 17 ... Wiring hole,
18 ... Base plate, 19 ... Mounting piece,
20 ... Control controller, 21 ... CPU, 22 ... ROM,
23 ... RAM, 24 ... data storage area, 25 ... pattern data,
26 ... Fade-in means, 27 ... Fade-out means,
30 ... Control BOX, 31 ... Changeover switch, 32 ... Operation switch,
33 ... Input unit, 34 ... Output unit, 35 ... Power adjustment unit,
36 ... A / D converter, 37 ... DC power supply,
40: Control unit,
COO: visible light (orange), CYY: visible light (yellow),
BLA ... UV.

Claims (4)

An ultraviolet lamp that emits ultraviolet light and a visible light lamp that emits visible light and emits a chromatic color are housed in one unit, and an illumination unit configured to irradiate a subject, and the ultraviolet light connected to the illumination unit A lighting device comprising a lamp and a controller for controlling the illuminance of the visible light lamp,
The control unit is provided with pattern data in which a pattern for controlling the illuminance of each lamp with time is stored, and a control controller for controlling the illuminance of each lamp based on the pattern data,
The pattern data includes fade-in means for gradually shifting the illuminance of each lamp from dark illuminance to bright illuminance, and fade-out means for gradually shifting the illuminance of each lamp from bright illuminance to dark illuminance. A lighting device characterized by the above. The pattern data includes a pattern in which the visible light lamp is lit at 100% illuminance when the maximum illuminance at the rated power of each lamp is 100% and the ultraviolet lamp is set to 100% illuminance. The lighting device according to claim 1. The lighting unit is provided with at least two visible light lamps of different chromatic colors,
The pattern data indicates that when the maximum illuminance at the rated power of each lamp is 100% and the ultraviolet lamp is set to 100% illuminance, at least one of the visible light lamps is lit at 100% illuminance. The illumination device according to claim 1, further comprising: An ultraviolet lamp that emits ultraviolet light and a visible light lamp that emits visible light and emits a chromatic color are housed in one unit, and an illumination unit configured to irradiate a subject, and the ultraviolet light connected to the illumination unit A lighting device comprising a lamp and a controller for controlling the illuminance of the visible light lamp,
The control unit is provided in correspondence with each lamp, an input unit that inputs a commercial AC power source, a power adjustment unit that adjusts a current or voltage of the power source input from the input unit, and the power adjustment unit An illumination device comprising: an operation switch that is connected and capable of adjusting the illuminance of each lamp; and an output unit that outputs electric power adjusted by the operation switch to the illumination unit.

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