This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2012-157686, filed on Jul. 13, 2012, the entire contents of which are incorporated herein by reference.
The present invention relates to a lighting device.
Japanese Utility Model No. 3159820 describes an example of a lighting device including a main power supply and a backup power supply. When the supply of power from the main power supply to a light source is interrupted, the light source is supplied with power from the backup power supply.
The lighting device of Japanese Utility Model No. 3159820 further includes a main light source and a backup light source. The backup light source is formed by an LED. When an abnormality occurs, the low power consumption backup (LED) light source is used so that the backup power supply, which is a rechargeable battery (battery cell), may be used for a relatively long time.
There is a demand for a lighting device that improves visibility under a mesopic vision environment. Japanese Laid-Open Patent Publication No. 2005-11812 discloses a lighting device that uses three LED light sources having different wavelengths and executes spectral control to generate light in accordance with a mesopic vision environment. Further, the lighting device of Japanese Laid-Open Patent Publication No. 2005-11812 uses LED light sources, and thus, consumes less power than fluorescent lamps and incandescent light bulbs.
Such a lighting device uses three types of LED light sources having different wavelengths to improve visibility under a mesopic vision environment. The LED light sources increase the number of components.
One aspect of the present invention is a lighting device provided with an illumination unit including two or less LED light sources. The illumination unit uses the two or less LED light sources to emit light of a short wavelength band and light of a long wavelength band. An output varying unit functions to vary an output of at least the long wavelength band light. When the output varying unit receives a varying signal, the output varying unit functions to decrease the output of at least the long wavelength band light.
Other aspects and advantages of the present invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
A lighting device 10 according to one embodiment of the present invention will now be described with reference to the drawings.
As shown in
The illumination unit 11 includes two LED light sources 21 and 22 and a fluorescent body 23. The LED light sources 21 and 22 emit different types of blue light. The fluorescent body 23 covers a light emitting surface of the LED light source 22. Further, the fluorescent body 23 emits yellow light when excited upon absorption of light from the LED light source 22. In the illumination unit 11, the LED light source 21 emits a short wavelength light, and the fluorescent body 23 and the LED light source 22 emit a long wavelength light.
As shown in
The backup activation circuit unit 32 is electrically connected to the charge unit 35. The output varying unit 38 and the switch circuit unit 33 connect the backup activation circuit unit 32 to the LED light source 21 of the illumination unit 11. The charge unit 35 is electrically connected to the power unit 36. The switch 37, which may be turned on and off, electrically connects the power unit 36 to the AC power supply D. When the switch 37 is turned on, the charge unit 35 accumulates power supplied from the AC power supply D through the power unit 36. The LED light source 22 is supplied with power from the charge unit 35 through the backup activation circuit unit 32. This allows for activation of the LED light source 22. In the present embodiment, the backup activation circuit unit 32 and the charge unit 35 form a backup power supply unit.
The activation detection unit 34 detects whether or not power is supplied from the AC power supply D to the main activation circuit unit 31. When the activation detection unit 34 determines that the LED light source 21 is not activated (deactivated) the activation detection unit 34 provides the output varying unit 38 with a varying signal.
Upon receipt of the varying signal, the output varying unit 38 controls the switch circuit unit 33 to switch to a power line extending through the backup activation circuit unit 32. More specifically, upon receipt of the varying signal, the output varying unit 38 functions to supply the power from the backup activation circuit unit 32 to the LED light source 21 through the output varying unit 38 and the switch circuit unit 33.
Examples of the operation of the lighting device 10 under normal and abnormal situations will now be described.
Under a normal situation, power is supplied from the AC power supply D to the main activation circuit unit 31. The main activation circuit unit 31 controls the activation of the two LED light sources 21 and 22. For example, when an activation operation is performed with an operation switch (not shown), the LED light sources 21 and 22 are activated, and the illumination unit 11 emits white light (refer to
When the supply of power from the AC power supply D is interrupted (abnormal situation) by a wire breakage or the like, the activation detection unit 34 provides the output varying unit 38 with a varying signal. Upon receipt of the varying signal, the output varying unit 38 controls the switch circuit unit 33 to switch to the power line extending through the backup activation circuit unit 32. Thus, the backup activation circuit unit 32 is supplied with power from the charge unit 35 instead of the AC power supply D. Then, for example, when an activation operation is performed with an operation switch (not shown), the LED light source 21 is activated, and the illumination unit 11 emits blue light (refer to
The human retina has photoreceptor cells including rods, which function under a mesopic vision situation or a scotopic vision situation. Thus, the activation of the LED light source 21 that emits short wavelength band light (e.g., blue light) improves visibility.
The lighting device 10 of the present embodiment has the advantages described below.
(1) The lighting device 10 includes the illumination unit 11, which includes the two LED light sources 21 and 22, and emit short wavelength band light and long wavelength band light, and the output varying unit 38, which is capable of varying the long wavelength band light output from the illumination unit 11. The output varying unit 38 decreases the output of the LED light source 22 to zero. The LED light source 22 is covered by the fluorescent body 23 that emits the long wavelength band light of the illumination unit 11. Further, the output varying unit 38 activates only the LED light source 21 that emits short wavelength band light. Rods function under a mesopic vision situation or a scotopic vision situation. Thus, the activation of the LED light source 21 that emits short wavelength band light (e.g., blue light) improves visibility. The use of the two LED light sources 21 and 22 as a light source reduces power consumption of the lighting device 10. Further, the number of the LED light sources 21 and 22 is reduced in comparison with the prior art. This, in turn, reduces the number of components of the lighting device 10.
(2) In the lighting device 10, when the power supplied to the illumination unit 11 is switched from the power from the main power supply unit to the power from the backup power supply unit, the activation detection unit 34 provides the output varying unit 38 with a varying signal. Upon receipt of the varying signal, the output varying unit 38 controls the switch circuit unit 33 to decrease the output of long wavelength band light. In this manner, changing the power supply source allows for the output varying unit 38 to decrease the output of long wavelength band light.
It should be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention. Particularly, it should be understood that the present invention may be embodied in the following forms.
Although not particularly mentioned above, in the above embodiment, the output varying unit 38 may be configured to gradually decrease the long wavelength band light. This allows for gradual shifting to only the short wavelength band light, and allows for reduction in the time used chromatic adaptation. Thus, a person would not feel discomfort with such a configuration.
Although not particularly mentioned above, in the above embodiment, white light may be emitted until a predetermined time elapses from when the output varying unit 38 is provided with a varying signal by combining short wavelength band light and long wavelength band light, and the output of the long wavelength band light may be decreased after the predetermined time elapses. More specifically, as shown in
In the above embodiment, the illumination unit 11 includes the two LED light sources 21 and 22 of substantially the same color (same wavelength band), and the LED light source 22 is covered by the fluorescent body 23 to emit white light. Instead, for example, referring to
In the above embodiment, the two LED light sources 21 and 22 are activated during a normal operation. Instead, referring to
In the above embodiment, during a normal operation and a backup operation, at least one of the LED light sources 21 and 22 is activated. However, there is no such limitation.
For example, referring to
For example, referring to
Although not particularly mentioned above, in the above embodiment, for example, referring to
In the above embodiment, the LED light source 22 emits long wavelength band light, and the fluorescent body 23 and the LED light source 21 emit short wavelength band light. Instead, for example, the illumination unit 11 may include a short wavelength light source unit and a long wavelength light source unit that emits, to the short wavelength light source, short wavelength band light having a relatively small output (spectral intensity) and long wavelength band light having a relatively large output. One such example will now be described.
The short wavelength light source unit includes, for example, an LED light source and a fluorescent body excited by the light of the LED light source. Referring to
The long wavelength light source unit includes, for example, an LED light source and a fluorescent body excited by the light of the LED light source. The long wavelength light source unit emits light of a short wavelength band having a relatively small light output and light of a long wavelength band having a relatively large light output to the short wavelength light source unit. For example, the long wavelength light source unit emits light including spectrum A, shown by the solid line in
In
Further, the long wavelength light source unit that emits the spectrum B, shown by the broken line in
In
In the lighting device configured in this manner, as shown in
When the supply of power from the AC power supply D is interrupted due to a wire breakage or the like, the activation detection unit 34 provides the output varying unit 38 with a varying signal. Upon receipt of the varying signal, the output varying unit 38 controls the switch circuit unit 33 to switch to the power line extending through the backup activation circuit unit 32. This supplies the backup activation circuit unit 32 with power from the charge unit 35 instead of the AC power supply D. Then, for example, when an activation operation is performed with an operation switch (not shown), only the short wavelength light source unit is activated, and the illumination unit 11 emits light having a correlated color temperature of 10000 K (refer to
Light having a correlated color temperature of 10000 K is in a correlated color temperature range (2500 K to 10000 K) used as an LED module for emitting white light as specified in JIS C8155:2010 “General Lighting LED Module, Capacity Requirements”. Thus, white light may be emitted during a backup operation. Further, when the long wavelength light source unit is deactivated, only the short wavelength light source unit having a relatively high color temperature is activated. As a result, the S/P ratio during the backup operation is higher than that during a normal operation. Further, the light from the short wavelength light source unit, as a single body, has an average color rendering index Ra of 70 or greater. Thus, sufficiently high color rendering may be maintained.
The short wavelength light source unit and the long wavelength light source unit of the above modified examples are activated with the same light flux during normal operation. However, the light flux ratio may be varied. Further, in the above modified examples, the long wavelength light source unit is activated. Instead, the long wavelength light source unit may be dimmed. In this manner, the long wavelength light source unit may be activated or dimmed so that in the light output of the light emitted from the illumination unit 11, the light output of the long wavelength band is greater than the light output of the short wavelength band. The short wavelength light source unit does not have to have the characteristics shown in
In the above embodiment, when receiving the varying signal, the output varying unit 38 supplies power from the backup activation circuit unit 32 to the LED light source 21 through the output varying unit 38 and the switch circuit unit 33. Instead, when receiving the varying signal, the output varying unit 38 may supply power from the backup activation circuit unit 32 through only the switch circuit unit 33. In this case, the activation detection unit 34 may provide the varying signal to the switch circuit unit 33 so that the switch circuit unit 33 switches to a power line extending through the backup activation circuit unit 32.
The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.
Number | Date | Country | Kind |
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2012-157686 | Jul 2012 | JP | national |