JP6722858B2 - Lighting equipment - Google Patents

Description

The present invention relates to a lighting device, and more particularly to a lighting device having an ion generating function.

Illumination devices that can emit ions have been known. For example, Patent Document 1 discloses a lighting device capable of emitting plasma ions and negative ions in order to decompose bacteria, fungi, harmful substances, etc. floating in the air.

JP, 2010-29552, A

An illumination device that can emit ions includes, for example, an illumination unit that emits illumination light and an ion emission unit that emits ions.

However, in the conventional lighting device capable of emitting ions, if the illumination unit is normal, even if the ion emission unit is abnormal, the user is unlikely to notice that the ion emission unit is abnormal. .. On the contrary, if the ion emission unit is normal, even if the illumination unit is abnormal, it is difficult for the user to notice that the illumination unit is abnormal. That is, if one of the illumination unit and the ion emission unit is normal, it is difficult to notice the abnormality even if the other is abnormal.

The present invention has been made to solve such a problem, and an object of the present invention is to provide an illumination device that allows a user to quickly recognize an abnormality in an illumination unit and an abnormality in an ion emission unit.

In order to achieve the above-mentioned object, one mode of an illuminating device according to the present invention comprises an illuminating unit that emits illuminating light and an ion emitting unit that emits ions, and the illuminating unit includes a first power supply/control. A block and a light source for illumination that emits light in a first illumination mode by electric power supplied from the first power supply/control block, and the ion emission unit includes a second power supply/control block and the second power supply/control block. No. 2 power supply/control block, an ion generation block operated by electric power supplied from the power supply/control block, and a display light source that emits light in a first operation display mode indicating an operation state of the ion generation block. The control block causes the illumination light source to emit light in a second illumination mode different from the first illumination mode when an abnormality occurs in the ion emission unit, and the second power source/control block When an abnormality occurs in the lighting unit, the display light source is caused to emit light in a second operation display mode different from the first operation display mode.

ADVANTAGE OF THE INVENTION According to this invention, the abnormality of an illumination unit and the abnormality of an ion emission unit can be promptly recognized by a user.

It is a perspective view which shows the state when the illuminating device which concerns on embodiment is installed in the ceiling. It is a block diagram which shows the structure of the illuminating device which concerns on embodiment. It is a figure which shows a mode that the light source for illumination in the illuminating device which concerns on embodiment emits light in the 1st illumination mode and the 2nd illumination mode. It is a figure which shows a mode that the light source for a display in the illuminating device which concerns on embodiment emits light in the 2nd operation display mode.

Hereinafter, embodiments of the present invention will be described. It should be noted that each of the embodiments described below shows a preferred specific example of the present invention. Therefore, the numerical values, shapes, materials, constituent elements, and the arrangement positions and connection forms of the constituent elements shown in the following embodiments are merely examples and are not intended to limit the present invention. Therefore, among the constituent elements in the following embodiments, the constituent elements that are not described in the independent claims showing the highest concept of the present invention are described as arbitrary constituent elements.

In addition, each drawing is a schematic view, and is not necessarily strictly illustrated. Therefore, the scales and the like do not necessarily match in each drawing. In each drawing, the substantially same components are designated by the same reference numerals, and overlapping description will be omitted or simplified.

(Embodiment)
A lighting device 1 according to the embodiment will be described with reference to FIGS. 1 and 2. FIG. 1 is a perspective view showing a state when the lighting device 1 according to the embodiment is installed on a ceiling. FIG. 2 is a block diagram showing the configuration of the lighting device 1 according to the embodiment.

The illuminating device 1 is, for example, a luminaire arranged on a building material such as a ceiling or a wall of a building such as a house or a store, and emits illuminating light to brighten a spatial area such as a room. Illumination device 1 in the present embodiment is installed on a ceiling, as shown in FIG. In this case, the lighting device 1 may be connected and fixed to a hook ceiling provided on the ceiling, may be directly fixed to the ceiling surface, or may be embedded in a through hole formed in the ceiling. It may have been done.

The lighting device 1 is installed, for example, on a ceiling or a wall surface such as an entrance, a shoe cloak, a walking closet, a toilet or a landing of stairs, but is not limited thereto. As will be described later, since the lighting device 1 has the functions of deodorizing/deodorizing and sterilizing, it is preferable to install the lighting device 1 at a location such as a toilet where the odor is a concern.

As shown in FIG. 1, the lighting device 1 includes a housing 10 and a translucent cover 20 provided in front of the housing 10. The housing 10 has, for example, a flat cylindrical shape. An illumination light source 120 is arranged inside the housing 10, and the light emitted from the illumination light source 120 passes through the translucent cover 20 and is emitted as illumination light. The translucent cover 20 is, for example, a diffusion cover that scatters and diffuses light. In this case, the illumination light emitted from the translucent cover 20 is diffused light.

Further, the lighting device 1 in the present embodiment is a lighting fixture having an ion generating function and emits ions. A plurality of slits 11 extending in the circumferential direction are formed on the side peripheral surface of the housing 10, and the generated ions are emitted from the slits 11 to the outside of the lighting device 1.

The ions emitted from the lighting device 1 are, for example, negative ions called NanoE (registered trademark). Nanoe is a negative ion surrounded by nanometer-sized (for example, about 5 to 20 nm in diameter) fine particle water, and is rich in OH radicals. Nanoe has an action of suppressing the activity of allergens (allergens) that have entered the air or the depths of fibers, and also has a deodorizing/deodorizing action, a bactericidal action and an antiviral action. Therefore, when Nanoe diffuses into the room, it deodorizes/deodorizes the space area or curtains in the room, inactivates allergens and viruses that are floating or adhering to the room, and floats or adheres to the room. It also removes molds and bacteria that are being used. In particular, nanoE has high reactivity and has the ability to act on odorous components and decompose into odorless components. Furthermore, Nanoe is mildly acidic to hair and skin and is useful for humans.

Nanoe can exist in the air for a long time (with a life of about 6 times that of negative ions) as compared with the case where only negative ions are present, and it is very small in nanometer size. 1 can be evenly dispersed in the entire space area in which 1 is installed and can float for a long time.

In this way, the illumination device 1 not only illuminates the spatial area with illumination light, but also emits ions into the spatial area. In the illuminating device 1, the power required to cause the illumination light source 120 to emit light is greater than the power required to generate ions. That is, in the present embodiment, the main function of the lighting device 1 is to illuminate with illumination light, and the emission of ions is an auxiliary function. As an example, the power required to emit the illumination light source 120 is 10 W, and the power required to generate ions is 5 W. Alternatively, the main function and the auxiliary function may be replaced with each other, and the main function of the lighting device 1 may be configured to emit ions and the auxiliary function may be configured to emit illumination light.

As shown in FIG. 2, the illumination device 1 includes an illumination unit 100 that emits illumination light, an ion emission unit 200 that emits ions, and a terminal block 300. The lighting unit 100, the ion emission unit 200, and the terminal block 300 are housed in the housing 10 shown in FIG.

The lighting unit 100 is a device for irradiating the space area in which the lighting device 1 is installed with illumination light, and includes a first power supply/control block 110, an illumination light source 120, and an illumination sensor block 130.

The first power supply/control block 110 is a power supply/control block for lighting, and controls a power supply function of generating electric power for causing the light source 120 for lighting to emit light and a lighting mode (light emitting state) of the light source 120 for lighting. It has a control function to operate.

The first power supply/control block 110 converts, for example, AC power supplied from the terminal block 300 into DC power, and the DC power is supplied to the illumination light source 120, so that the illumination light source 120 emits light. The first power supply/control block 110 has an H terminal (first terminal), an N terminal (second terminal), and an LOD terminal (third terminal). The H terminal and the N terminal are connected to the terminal block 300, and the AC power supplied from the terminal block 300 to the first power supply/control block 110 is input to the H terminal and the N terminal. The LOD terminal is connected to the second power supply/control block 210.

In addition, the first power supply/control block 110 performs lighting control of the lighting light source 120, color matching control, and blinking/flashing control of the lighting light source 120, thereby illuminating the lighting source 120. To change.

The first power/control block 110 includes a mounting board and a plurality of circuit elements mounted on the mounting board. The plurality of circuit elements include a power supply circuit element that configures a power supply circuit that generates electric power for causing the illumination light source 120 to emit light, and a control circuit element that configures a control circuit that controls the illumination mode of the illumination light source 120. Be done.

The illumination light source 120 is a light source module that serves as a light source unit of the illumination device 1, and emits, for example, white light as illumination light for the illumination device 1 to illuminate a spatial region. In the present embodiment, the illumination light source 120 is an LED module using an LED (Light Emitting Diode) as a light source. As an example, the illumination light source 120 is a COB (Chip On Board) type, and includes a substrate, a plurality of LED chips mounted on the substrate, and a sealing member that seals the LED chips.

As the substrate, a ceramic substrate, a resin substrate, a metal base substrate or the like is used. The LED chip is, for example, a bare chip that emits visible light of a single color. The LED chip is a blue LED chip that emits blue light when energized. The sealing member is, for example, a translucent resin. The sealing member in the present embodiment includes a phosphor as a wavelength conversion material that converts the wavelength of light from the LED chip. The sealing member is, for example, a phosphor-containing resin in which a phosphor is dispersed in a silicone resin. As the phosphor particles, when the LED chip is a blue LED chip, for example, a YAG-based yellow phosphor can be used to obtain white light. In the present embodiment, the sealing member is formed in a circular shape so as to collectively seal all the LED chips, but a plurality of LED chips may be sealed in a line for each column, Each LED chip may be individually sealed.

The illumination light source 120 has a dimmable structure and a color-tunable structure. The illumination light source 120 is fixed at a predetermined position in the housing 10 by a fixing member such as a screw or an adhesive.

The illumination light source 120 emits light in a predetermined illumination mode by the power supplied from the first power supply/control block 110 so that the illumination light is emitted from the illumination device 1. For example, the illumination light source 120 emits light in the first illumination mode by the electric power supplied from the first power supply/control block 110 when the ion emission unit 200 is operating normally.

Specifically, the blue LED chip of the illumination light source 120 emits light by the DC power supplied from the first power supply/control block 110. As a result, part of the blue light of the blue LED chip is absorbed and excited by the yellow phosphor, and the yellow light is emitted from the yellow phosphor. Then, the yellow light and the blue light not absorbed by the yellow phosphor are mixed to become white light, and the illumination light source 120 emits white light. In the present embodiment, the first illumination mode of the illumination light source 120 is a mode in which the illumination light source 120 emits light (all lights) with a light output of 100%.

In addition, the illumination light source 120 emits light in a second illumination mode different from the first illumination mode by the power supplied from the first power supply/control block 110 when an abnormality occurs in the ion emission unit 200. ..

The second illumination mode of the illumination light source 120 is a brightness different from the brightness of the first illumination mode, a light color different from the light color of the first illumination mode, blinking, flash lighting, or the like. In this case, the light source 120 for illumination is dimmed by the first power supply/control block 110 to cause the light source 120 for illumination to emit light in a second illumination mode having a brightness different from the brightness of the first illumination mode. You can Further, by adjusting the color of the illumination light source 120 by the first power supply/control block 110, the illumination is performed in the second illumination mode of the light color different from the light color (chromaticity, color temperature) of the first illumination mode. The light source 120 can also be made to emit light. Further, by transmitting a blinking/flash lighting control signal from the first power supply/control block 110 to the illumination light source 120, the illumination light source 120 can be regularly blinked as the second illumination mode.

In the present embodiment, the second illumination mode of the illumination light source 120 has a brightness that is darker than the brightness of the first illumination mode. In this case, for example, when the light source 120 for illumination is dimmed and dimmed by the first power supply/control block 110, the light source 120 for illumination emits light in the first illumination mode as the second illumination mode. It illuminates light with a lower light output than that of.

The illumination sensor block 130 is, for example, a sensor unit including a human sensor and an illuminance sensor. The human sensor is a sensor for detecting the presence or absence of a person around the lighting device 1. For example, when a human presence sensor detects a detection signal (human presence signal) indicating the presence of a person, the illumination light source 120 emits light. The illuminance sensor is a sensor for detecting the illuminance of light around the illumination device 1. For example, when the illuminance sensor detects a detection signal indicating the illuminance (illuminance signal) and the illuminance value based on the detection signal is lower than a predetermined illuminance value, the illumination light source 120 emits light.

The ion emitting unit 200 is a device having a function of emitting ions to a space area where the lighting device 1 is installed. By releasing ions from the ion releasing unit 200 for a certain period of time, it is possible to deodorize/deodorize the space area, inactivate allergens, viruses, etc., and sterilize molds, bacteria, etc. in the space area. In order to obtain a deodorizing effect of 90% in a space area of about 2 tatami mats of a house, it is advisable to release nanoe for about 8 hours.

The ion emission unit 200 includes a second power/control block 210, an ion generation block 220, a display light source 230, and a blower 240.

The second power supply/control block 210 has a power supply function of generating electric power for operating the ion generation block 220 and the blower 240 and generating electric power for causing the display light source 230 to emit light, and also has the display light source 230. It has a control function for controlling the operation display mode (light emitting state).

The power supply source of the second power supply/control block 210 is the first power supply/control block 110. That is, AC power is supplied from the first power supply/control block 110 to the second power supply/control block 210. Specifically, the AC power supplied to the second power supply/control block 210 is supplied from the LOD terminal of the first power supply/control block 110 and one terminal of the terminal block 300. With this configuration, the configuration for supplying power to the ion emission unit 200 can be simplified. Moreover, since the second power source/control block 210 and the first power source/control block 110 share the power source, the first power source/control block 110 is provided with a countermeasure circuit against noise, surge, and inrush current. By mounting, the countermeasure circuit in the second power supply/control block 210 on the subsequent stage can be simplified. That is, the countermeasure circuit can be shared by the first power supply/control block 110 and the second power supply/control block 210.

Further, in the present embodiment, the delay time is set when power is supplied from the second power supply/control block 210 to the first power supply/control block 110. As a result, the ion emitting unit 200 side can be reset, so that malfunction can be prevented.

The second power supply/control block 210 supplies a predetermined electric power to each of the ion generation block 220 and the blower 240 to operate the ion generation block 220 and the blower 240. Further, the second power supply/control block 210 supplies a predetermined electric power to the display light source 230 to cause the display light source 230 to emit light. Specifically, the second power supply/control block 210 converts the AC power supplied from one terminal of the terminal block 300 and the LOD terminal of the first power supply/control block 110 into DC power, and this DC power is supplied. Is supplied to the display light source 230, the display light source 230 emits light.

Further, the second power supply/control block 210 controls the ion generation block 220 and the blower 240. For example, the second power supply/control block 210 controls the start and stop of the operation of the ion generation block 220 and the blower 240 (that is, the ion emission time), and controls the amount of ions emitted from the ion emission unit 200. Control. Further, the second power supply/control block 210 illuminates the display light source 230 by performing dimming control, toning control, flashing control, or flash lighting control on the display light source 230. Change the mode.

The second power supply/control block 210 is composed of a mounting board and a plurality of circuit elements mounted on the mounting board.

Specifically, the plurality of circuit elements forming the second power supply/control block 210 include drive circuit elements forming a drive circuit for driving the ion generation block 220 and the blower 240. The drive circuit element includes a power supply circuit element that constitutes a power supply circuit that generates electric power for operating the ion generation block 220 and the blower 240, and a control circuit that controls the ion generation block 220 and the blower 240. And a control circuit element. The drive circuit element for the ion generation block and the drive circuit element for the blower may be mounted on the same mounting board or may be mounted on different mounting boards.

In addition, the plurality of circuit elements forming the second power supply/control block 210 include a power supply circuit element forming a power supply circuit that generates electric power for causing the display light source 230 to emit light, and an illumination mode of the display light source 230. And a control circuit element forming a control circuit for controlling the.

The ion generation block 220 is an ion generator for generating ions. In the present embodiment, the ion generation block 220 generates nanoE. Specifically, the ion generation block 220 generates nanoe without water supply. In this case, the ion generation block 220 includes, for example, a needle-shaped discharge electrode, a high-voltage generation circuit that applies a high voltage (for example, about 6000 V) to the needle-shaped discharge electrode, and a Peltier element that cools the needle-shaped discharge electrode. It has an ion generating part. The needle-shaped discharge electrode is condensed by being cooled by the Peltier effect of the Peltier element. By applying a high voltage to the water in the air condensed on the needle-shaped discharge electrode by the high-voltage generation circuit, atomized nanoe can be generated. Ions (nanoe) generated by the ion generation block are emitted to the outside of the casing 10 through the slits 11 provided in the casing 10. In the present embodiment, since blower 240 is arranged in front of ion generation block 220, it is blown out of casing 10 along with the outside air taken in by blower 240.

The ion generation block 220 configured as described above operates by the electric power supplied from the second power supply/control block 210. That is, ions are generated by supplying power from the second power supply/control block 210 to the ion generation block 220.

The display light source 230 emits light in an operation display mode indicating the operation state of the ion generation block 220. That is, the display light source 230 is an indicator showing the operating state of the ion generation block 220.

As the display light source 230, for example, a cannonball type LED element can be used, but the display light source 230 is not limited to this, and an SMD (Surface Mount Device) type package type LED element may be used, or a small COB. A type of LED module may be used. The display light source 230 emits colored light such as blue or green, but is not limited thereto. The illumination light source 120 emits monochromatic light with a constant light output, but may have a structure capable of controlling dimming and toning. The display light source 230 is fixed at a predetermined position in the housing 10.

The display light source 230 emits light in a predetermined operation display mode by the electric power supplied from the second power supply/control block 210 so that whether or not the lighting device 1 emits ions can be known. For example, the display light source 230 emits light in the first operation display mode by the power supplied from the second power supply/control block 210 when the ion emission unit 200 and the illumination unit 100 are operating normally.

That is, the first operation display mode of the display light source 230 is a mode showing that the ion generation block 220 and the blower 240 are normally driven and ions are emitted from the ion emission unit 200. For example, when the display light source 230 emits light in the first operation display mode, the display light source 230 normally emits light. As an example, when the display light source 230 is a bullet-type blue LED element, the display light source 230 emits blue light having a constant light output as the first operation display mode. As the display light source 230 emits light in the first operation display mode in this manner, the user can know that the ions are emitted from the ion emission unit 200.

Further, the display light source 230 emits light in a second operation display mode different from the first operation display mode by the power supplied from the second power supply/control block 210 when an abnormality occurs in the lighting unit 100. To do.

The second illumination mode of the display light source 230 is a brightness different from the brightness of the first operation display mode, a light color different from the light color of the first operation display mode, blinking or flash lighting. In the present embodiment, the second illumination mode of the display light source 230 is blinking. In this case, by transmitting a blinking control signal from the second power supply/control block 210 to the display light source 230, the display light source 230 can be regularly blinked as the second illumination mode. When the display light source 230 can control dimming and color adjustment, the second power source/control block 210 dimmes or colors the display light source 230 to obtain the first operation display mode. The display light source 230 is caused to emit light in a second operation display mode having a brightness different from the brightness, or a second operation display having a light color different from the light color (chromaticity, color temperature) of the first operation display mode. The display light source 230 can be caused to emit light in this manner.

The blower 240 is a blower fan that blows the ions generated by the ion generation block 220. Specifically, the blower 240 is for generating an air flow for diffusing the ions generated by the ion generation block 220 to the outside of the lighting device 1. That is, the blower 240 assists the diffusion of the ions generated by the ion generation block 220 by blowing air. The blower 240 has, for example, a casing, an impeller arranged inside the casing, and a motor for rotating the impeller, and sucks and discharges air (outside air) outside the lighting device 1. When the blower 240 is operated, the outside air is sucked into the housing 10 from the suction port provided in the housing 10, and the sucked outside air is discharged from the slit 11 of the housing 10 together with the ions generated in the ion generation block 220. It is discharged to the outside of the housing 10.

In addition, a filter 400 through which the outside air sucked by the blower 240 passes is provided in the housing 10. The filter 400 is arranged, for example, between the suction port of the housing 10 and the blower 240. By passing the outside air through the filter 400, it is possible to adsorb and remove dust, dust, and the like contained in the outside air to the filter 400.

The terminal block 300 is connected to a commercial power source by an electric wire or the like. The terminal block 300 and the commercial power source are electrically connected via the wall switch 2. That is, the lighting device 1 and the commercial power supply are electrically connected via the wall switch 2.

Here, the operation of the illumination device 1 according to the present embodiment will be described below with reference to FIG.

The lighting device 1 is operated by the wall switch 2. For example, when the wall switch 2 shown in FIG. 2 is pressed, the illumination light source 120 emits light in the first illumination mode and illumination light is emitted from the illumination device 1, and ions are generated in the ion generation block 220. As a result, ions are emitted from the lighting device 1.

Specifically, when the user presses the wall switch 2, AC power is supplied from the commercial power supply to the terminal block 300 of the lighting device 1. The AC power supplied to the terminal block 300 is input to the H terminal and the N terminal of the first power supply/control block 110. The first power supply/control block 110 converts AC power from the terminal block 300 into DC power and outputs the DC power to the illumination light source 120. Thereby, the illumination light source 120 emits light in the first illumination mode.

Note that when a certain time (for example, 10 minutes) has elapsed since the power supply to the illumination light source 120 was started, the first power supply/control block 110 stops the power supply to the illumination light source 120. That is, when the light emission of the illumination light source 120 in the first illumination mode has passed for a certain time, the illumination light source 120 is automatically turned off.

On the other hand, when the user presses the wall switch 2, AC power is also supplied to the second power supply/control block 210 via the terminal block 300 and the LOD terminal of the first power supply/control block 110. The second power supply/control block 210 supplies electric power to the ion generation block 220, the blower 240, and the display light source 230. As a result, the ion generation block 220 and the blower 240 are driven to emit ions from the ion emission unit 200, and at the same time, the display light source 230 emits light in the first operation display mode. When the display light source 230 emits light in the first operation display mode, the user can know that the ions are emitted from the ion emission unit 200.

It should be noted that the ion emission block 200 remains in the ON state and emits ions for a certain time (for example, 10 hours) after the power supply to the ion generation block 220, the blower 240, and the display light source 230 is started, but the ions are constantly emitted. When the time has elapsed, the second power supply/control block 210 stops the power supply to the ion generation block 220, the blower 240, and the display light source 230. As a result, the ion emission from the ion emission unit 200 is automatically stopped and the display light source 230 is automatically turned off. By turning off the display light source 230, the user knows that the ion generation block 220 and the blower 240 are not driven and ions are not emitted from the ion emission unit 200.

The illumination device 1 also operates by detecting a predetermined detection signal with the illumination sensor block 130 without the user pressing the wall switch 2. For example, when the illuminance sensor of the illumination sensor block 130 detects a signal whose illuminance around the illumination device 1 is lower than a predetermined threshold as the detection signal, the human sensor of the illumination sensor block 130 further detects the signal as the detection signal. When it is detected that a person is present around the lighting device 1, the first power supply/control block 110 causes the lighting light source 120 to automatically emit light in the first lighting mode.

In the present embodiment, the light emission of the display light source 230 and the ion emission of the ion emission unit 200 are started at the same time. However, the light emission duration of the display light source 230 (for example, 10 minutes) and the ion emission unit 200 are changed. Since it is significantly different from the ion emission duration time (for example, 10 hours), it is not always necessary to start emission of light from the display light source 230 and start emission of ions from the ion emission unit 200 at the same time.

Next, characteristic control of the lighting device 1 according to the present embodiment will be described with reference to FIG. 2 and with reference to FIGS. 3 and 4. FIG. 3 is a diagram showing how the illumination light source 120 in the illumination device 1 according to the embodiment emits light in the first illumination mode and the second illumination mode. FIG. 4 is a diagram showing how the display light source 230 in the illumination device 1 according to the embodiment emits light in the second operation display mode.

In the illumination device 1 according to the present embodiment, the first power supply/control block 110 uses the illumination light source 120 in the second illumination mode different from the first illumination mode when an abnormality occurs in the ion emission unit 200. Light up. Specifically, when an abnormality occurs in the ion emission unit 200, as shown in FIG. 2, the ion emission unit 200 is transferred from the second power/control block 210 to the first power/control block 110 via a signal line. The first abnormality signal S1 indicating that is abnormal is input. As a result, the first power supply/control block 110 determines that an abnormality has occurred in the ion emission unit 200, and causes the illumination light source 120 to emit light in the second illumination mode.

In the present embodiment, the second illumination aspect of the illumination light source 120 is darker than the first illumination aspect of the illumination light source 120. That is, the illumination light in the second illumination mode is the illumination light in the first illumination mode. Therefore, when the ion emission unit 200 is operating normally, the illumination light source 120 emits light in the first illumination mode (100% dimming), as shown in FIG. When an abnormality occurs in 200, as shown in FIG. 3B, the illumination light source 120 emits light in the second illumination mode (for example, 50% dimming). As a result, the user feels that the illumination light of the illumination device 1 is darker than in the normal first illumination mode, and thus can recognize that something is wrong with the ion emission unit 200.

The abnormality of the ion emission unit 200 is, for example, that the filter 400 is in a clogged state. That is, when the filter 400 becomes clogged, the first power supply/control block 110 causes the illumination light source 120 to emit light in the second illumination mode.

Further, the abnormality of the ion emitting unit 200 may be that the temperature inside the ion emitting unit 200 exceeds a predetermined threshold value, that the ion emitting unit 200 has failed, or the ion emitting unit 200 is defective. It may be that the life remaining period of 200 is below a predetermined threshold value. Also in these cases, the first power supply/control block 110 causes the illumination light source 120 to emit light in the second illumination mode.

On the other hand, when an abnormality occurs in the lighting unit 100, the second power supply/control block 210 causes the display light source 230 to emit light in the second operation display mode different from the first operation display mode. Specifically, when an abnormality occurs in the lighting unit 100, as shown in FIG. 2, the ion emission unit 200 is transferred from the first power/control block 110 to the second power/control block 210 via a signal line. A second abnormality signal S2 indicating an abnormality is input. As a result, the second power supply/control block 210 determines that an abnormality has occurred in the lighting unit 100, and causes the display light source 230 to emit light in the second operation display mode.

In the present embodiment, the second operation display mode of the display light source 230 is blinking. Therefore, when an abnormality occurs in the lighting unit 100, the display light source 230 repeats the lighting state of FIG. 4A and the OFF state of FIG. 4B for a certain period of time. Accordingly, the user feels that the display light source 230 is turned on in a mode different from the normal first display operation mode, and thus can recognize that some abnormality has occurred in the lighting unit 100. ..

The abnormality of the lighting unit 100 is, for example, that the temperature inside the lighting unit 100 exceeds a predetermined threshold value. Further, the abnormality of the lighting unit 100 may be that the lighting unit 100 has failed, or that the life remaining period of the lighting unit 100 is below a predetermined threshold value.

As described above, in the lighting device 1 according to the present embodiment, the lighting unit 100 and the ion emitting unit 200 are connected by the signal lines connected to the first power supply/control unit 110 and the second power supply/control unit 210. The operation information is shared with each other, the abnormality that occurs in one is notified to the other, and the existing illumination light source 120 and the display light source 230 are used to let the user recognize the abnormality.

As described above, the illumination device 1 according to the present embodiment includes the illumination unit 100 that emits illumination light and the ion emission unit 200 that emits ions. The lighting unit 100 includes a first power supply/control block 110, and a lighting light source 120 that emits light in a first lighting mode by electric power supplied from the first power supply/control block 110. The ion emission unit 200 includes a second power supply/control block 210, an ion generation block 220 that operates by electric power supplied from the second power supply/control block 210, and a first operation state of the ion generation block 220. And a display light source 230 that emits light in an operation display mode. Then, the first power supply/control block 110 causes the illumination light source 120 to emit light in the second illumination mode different from the first illumination mode when an abnormality occurs in the ion emission unit 200, and the second power source. The control block 210 causes the display light source 230 to emit light in the second operation display mode different from the first operation display mode when an abnormality occurs in the lighting unit 100.

With this configuration, even if the illumination unit 100 is normal, if the ion emission unit 200 has an abnormality, the user can recognize that the ion emission unit 200 has an abnormality. On the contrary, if the illumination unit 100 is abnormal even if the ion emission unit 200 is normal, the user can be made aware that the illumination unit 100 is abnormal. As described above, according to the illumination device 1 in the present embodiment, it is possible for the user to promptly recognize the abnormality of the illumination unit 100 and the abnormality of the ion emission unit 200. Therefore, the user can promptly take measures to resolve the abnormality.

In addition, in the illumination device 1 according to the present embodiment, the ion emission unit 200 further includes a blower 240 that blows the ions generated by the ion generation block 220.

With this configuration, the ions generated by the ion generation block 220 can be efficiently diffused around the illumination device 1.

Further, lighting device 1 in the present embodiment further includes filter 400 through which the outside air sucked by blower 240 passes, and the abnormality of ion emission unit 200 is that filter 400 is in a clogged state. ..

When the filter 400 is in a clogged state, the ability of the blower 240 to blow ions is reduced, and the amount of ions emitted from the ion emission unit 200 is reduced or the ions are less likely to diffuse. Therefore, in an attempt to maintain the ion emission performance of the ion emission unit 200, the ion emission unit 200 increases the air blowing ability of the blower 240 or increases the amount of ions generated by the ion generation block 220, so The input power to 240 and the ion generation block 220 increases. Therefore, the internal temperature of the ion emitting unit 200 rises, and as a result, the life of the ion emitting unit 200 is shortened or the ion emitting unit 200 fails.

On the other hand, in the present embodiment, when the filter 400 becomes clogged, it is determined that an abnormality has occurred in the ion emission unit 200, and the illumination light source 120 emits light in the second illumination mode.

With this configuration, the user can recognize that the filter 400 is in the clogged state, so that the filter 400 can be replaced or the filter 400 can be washed. As a result, it is possible to prevent the life of the ion emission unit 200 from decreasing and the ion emission unit 200 from malfunctioning.

Moreover, in the present embodiment, when the illumination light source 120 emits light in the second illumination state, it emits light with less light than in the first illumination state. As a result, the electric power supplied to the illumination light source 120 is reduced, and the internal temperature of the illumination unit 100 is reduced. Therefore, even if the internal temperature of the ion emission unit 200 rises due to the clogging of the filter 400, the internal temperature of the lighting unit 100 can be lowered, and the temperature of the lighting device 1 as a whole can be balanced. That is, even if the filter 400 continues to be clogged and the internal temperature of the ion emission unit 200 rises, the internal temperature of the lighting unit 100 is lowered, and the temperature rise of the lighting device 1 as a whole can be suppressed. .. As a result, it is possible to prevent the life of the lighting device 1 from being shortened and the lighting device 1 from malfunctioning as the temperature rises.

Further, in the illumination device 1 according to the present embodiment, the abnormality of the ion emission unit 200 may be that the temperature inside the ion emission unit 200 exceeds a predetermined threshold value or that the ion emission unit 200 fails. Good.

With this configuration, when the temperature in the ion emission unit 200 exceeds a predetermined threshold value or when the ion emission unit 200 fails, it is determined that an abnormality has occurred in the ion emission unit, and the illumination light source 120 is set to the first. Light is emitted in the illumination mode of No. 2. This allows the user to recognize that the temperature inside the ion emission unit 200 has exceeded a predetermined threshold value, so that, for example, the lighting device 1 is temporarily turned off or the ion emission unit 200 (ion generation block 220, blower). By stopping the operation of 240) or suppressing an increase in the internal temperature of the lighting device 1, it is possible to suppress a decrease in the life of the lighting device 1 due to the temperature increase. Further, even if the lighting unit 100 is normal, it is possible to let the user recognize that the ion emission unit 200 has failed, so that the user can recognize that ions are not emitted from the illumination device 1. This allows the ion ejection unit 200 to be promptly repaired or replaced.

Further, in the lighting device 1 according to the present embodiment, the abnormality of the ion emitting unit 200 is that the life remaining period of the ion emitting unit 200 is below a predetermined threshold.

With this configuration, when the life remaining period of the ion emission unit 200 falls below a predetermined threshold value, it is determined that an abnormality has occurred in the ion emission unit 200, and the illumination light source 120 emits light in the second illumination mode. This allows the user to recognize that the ion emission unit 200 is approaching the end of its life, so that the ion emission unit 200 can reach the end of its life and no more ions are emitted from the lighting device 1. Can be exchanged. Therefore, it is possible to avoid sudden disappearance of ions from the lighting device 1, and thus it is possible to maintain the effect (deodorizing effect, etc.) of the ions.

Further, in the lighting device 1 according to the present embodiment, the abnormality of the lighting unit 100 is that the temperature inside the lighting unit 100 has exceeded a predetermined threshold value or that the lighting unit 100 has failed.

With this configuration, when the temperature inside the lighting unit 100 exceeds a predetermined threshold value or when the lighting unit 100 fails, it is determined that an abnormality has occurred in the lighting unit 100, and the display light source 230 has the second light source. Light is emitted in the operation display mode. This allows the user to recognize that the temperature in the lighting unit 100 has exceeded the predetermined threshold value, so that, for example, the lighting device 1 is temporarily turned off or the ion emission unit 200 (ion generation block 220, blower 240). By stopping the operation of (1) or suppressing an increase in the internal temperature of the lighting device 1, it is possible to suppress a decrease in the life of the lighting device 1 due to the temperature increase. Further, even if the ion emission unit 200 is normal, the user can recognize that the lighting unit 100 has failed, so that the lighting unit 100 can be promptly repaired or replaced.

Further, in the lighting device 1 according to the present embodiment, the abnormality of the lighting unit 100 is that the life remaining period of the lighting unit 100 is below a predetermined threshold.

With this configuration, when the life remaining period of the lighting unit 100 falls below a predetermined threshold value, it is determined that an abnormality has occurred in the lighting unit 100, and the display light source 230 emits light in the second operation display mode. With this, the user can recognize that the life of the lighting unit 100 is approaching, so that the illumination unit 100 is illuminated before the illumination light, which is the main function of the lighting device 1, is no longer emitted. The unit 100 can be replaced. Therefore, it is possible to prevent the lighting device 1 from suddenly not turning on.

In the lighting device 1 according to the present embodiment, the second lighting mode has a brightness different from the brightness of the first lighting mode, a light color different from the light color of the first lighting mode, blinking or flash lighting. Is.

This allows the user to easily recognize the abnormality of the ion emission unit 200.

In this case, it is preferable that the second illumination mode be darker than the first illumination mode.

As a result, the electric power supplied to the illumination light source 120 is reduced, and the internal temperature of the illumination unit 100 is reduced. Therefore, it is possible to make the user recognize the abnormality of the ion emission unit 200 without shortening the life of the illumination device 1 due to the temperature rise.

In the lighting device 1 according to the present embodiment, the second operation display mode has a brightness different from the brightness of the first lighting mode, a light color different from the light color of the first lighting mode, blinking or flashing. It is lit.

This allows the user to easily recognize the abnormality of the lighting unit 100.

(Modification)
Although the illumination device according to the present invention has been described above based on the embodiment, the present invention is not limited to the above embodiment.

For example, in the above-described embodiment, the ion emitting unit 200 emits nanoe as an ion. However, the present invention is not limited to this, and other ions such as plasma ions may be emitted, or nanoe and plasma ions may be emitted. The plural types of ions may be released simultaneously or alternately.

Further, although the illumination light source 120 is the COB type LED module in the above-described embodiment, the illumination light source 120 is not limited to this. For example, an SMD type LED module may be used as the light source for illumination. The SMD type LED module is a package type LED device (LED of a SMD type) in which an LED chip is mounted in a recess of a resin package (container) and a sealing member (phosphor-containing resin) is enclosed in the recess. One or a plurality of LED elements) are mounted on the substrate.

Further, in the above-described embodiment, the illumination light source 120 is the BY type white LED light source that emits white light by the blue LED chip and the yellow phosphor, but the illumination light source 120 is not limited to this. For example, a phosphor-containing resin containing a red phosphor and a green phosphor may be used, and the resin may be combined with a blue LED chip to emit white light. Further, in addition to the yellow phosphor, a red phosphor or a green phosphor may be further mixed for the purpose of enhancing the color rendering property. Further, an LED chip that emits a color other than blue may be used, and for example, an ultraviolet LED chip that emits ultraviolet light having a shorter wavelength than the blue light emitted by the blue LED chip is used and is mainly excited by ultraviolet light. The blue phosphor, the green phosphor, and the red phosphor that emit blue light, red light, and green light may emit white light.

In addition, it is realized by making various modifications to those skilled in the art by those skilled in the art, and by arbitrarily combining the components and functions of each embodiment without departing from the spirit of the present invention. The present invention also includes the forms.

1 Lighting Device 2 Wall Switch 100 Lighting Unit 110 First Power Supply/Control Block 120 Lighting Light Source 130 Lighting Sensor Block 200 Ion Emission Unit 210 Second Power Supply/Control Block 220 Ion Generation Block 230 Display Light Source

Claims (10)

An illumination unit that emits illumination light,
And an ion emitting unit that emits ions,
The lighting unit includes a first power supply/control block and a lighting light source that emits light in a first lighting mode by electric power supplied from the first power supply/control block.
The ion emission unit includes a second power supply/control block, an ion generation block operated by electric power supplied from the second power supply/control block, and a first operation display indicating an operation state of the ion generation block. And a display light source that emits light in an aspect,
The first power supply/control block causes the illumination light source to emit light in a second illumination mode different from the first illumination mode when an abnormality occurs in the ion emission unit,
The second power supply/control block causes the display light source to emit light in a second operation display mode different from the first operation display mode when an abnormality occurs in the lighting unit,
Lighting equipment. The ion emission unit further includes a blower that blows the ions generated by the ion generation block,
The lighting device according to claim 1. Furthermore, a filter through which the outside air sucked by the blower passes is provided,
The abnormality of the ion emission unit is that the filter is in a clogged state,
The lighting device according to claim 2. The abnormality of the ion emitting unit is that the temperature in the ion emitting unit exceeds a predetermined threshold value, or the ion emitting unit has failed,
The lighting device according to claim 1. The abnormality of the ion emitting unit is that the life remaining period of the ion emitting unit is below a predetermined threshold,
The lighting device according to claim 1. The abnormality of the lighting unit is that the temperature in the lighting unit exceeds a predetermined threshold value, or the lighting unit has failed,
The lighting device according to any one of claims 1 to 5. The abnormality of the lighting unit is that the life remaining period of the lighting unit is below a predetermined threshold,
The lighting device according to any one of claims 1 to 5. The second illumination mode is a brightness different from the brightness of the first illumination mode, a light color different from the light color of the first illumination mode, blinking or flash lighting.
The lighting device according to any one of claims 1 to 7. The second illumination mode has a darker brightness than the brightness of the first illumination mode,
The lighting device according to any one of claims 1 to 7. The second operation display mode is a brightness different from the brightness of the first illumination mode, a light color different from the light color of the first illumination mode, blinking or flash lighting.
The lighting device according to any one of claims 1 to 9.

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