JP2022178017A - Lighting apparatus - Google Patents

Abstract

To provide a lighting apparatus and a power failure detection device capable of being utilized as a disaster prevention light in power failure by including a storage battery in the lighting apparatus.SOLUTION: A lighting apparatus includes: a mounting adaptor fitted to an opening portion of a main body 10 composed of a substantially circular flat plate and connected to a fixture of a ceiling; a light source 30 composed of a plurality of U-shaped substrates 40 substantially annularly disposed on a front surface of the main body 10 for mounting a plurality of LEDs; a remote controller light receiving sensor 55 receiving a transmission signal from an external remote controller; a pairing switch 60; an antenna 67 transmitting/receiving signals to a power failure detection device; and a power source device 50 and a storage battery 69 for making the light source 30 emit light. The power failure detection device is disposed on a power receptacle and detects power failure of a commercial power source and transmits a power failure detection signal to the lighting apparatus by being connected to the lighting apparatus for pairing. The lighting apparatus lights the light source 30 for a long time by supplying light to the light source 30 from the storage battery 69.SELECTED DRAWING: Figure 4B

Description

The present invention relates to a lighting fixture such as a ceiling light using a light-emitting element such as an LED that can be used as a normal lighting fixture in normal times and as a disaster prevention lighting fixture in an emergency.

In general, lighting fixtures such as ceiling lights using light-emitting elements such as LEDs are widely used in general buildings such as general single-family houses and collective housing. Lighting fixtures such as ceiling lights are usually supplied with commercial power from fixtures (wiring fixtures) installed on the ceiling (fixture mounting surface). Lighting, extinguishing, etc. are operated by an operation or the like.

If a natural disaster such as an earthquake or typhoon occurs, or if there is a problem with the power generation equipment, and the supply of commercial power is interrupted, or if an overcurrent occurs in the house and the safety breaker trips to cut off the power supply, a power outage will occur and the lighting will be cut off. The fixture will suddenly turn off. Especially when there is a power outage at night, you have to fumble around in the dark looking for lights such as flashlights, lanterns, and candles. It will be.
In such a case, the lighting equipment installed on the ceiling is equipped with a disaster prevention (emergency) lighting device. It can reduce people's anxiety.

Therefore, as a countermeasure against sudden power outages, lighting fixtures equipped with an emergency power source are known. When this lighting fixture detects a power failure, it lights up with power supplied from an emergency power source consisting of a battery, and serves as an emergency light (Patent Document 1).

JP-A-10-92586

In Patent Document 1, a battery is installed in a lighting fixture, and when a power failure occurs while a remote control transmitter is connected to a power outlet, the remote control transmitter transmits a signal to turn on the lighting fixture with the battery, and power is supplied from the battery. to light a lighting fixture consisting of a fluorescent lamp. However, this lighting fixture is a circular ceiling light that uses fluorescent lamps, and because it requires more power than light-emitting elements such as LEDs, it consumes a large amount of battery power and cannot be lit for a relatively short period of time. In order to secure a certain amount of lighting time, which is limited, it is necessary to deploy a large-capacity battery. There was a problem that the operation of was limited to the remote control transmitter.

Therefore, in order to solve the problems of the prior art documents, the present invention provides a lighting fixture using a light emitting element such as an LED as a light source, and a power failure detection device having a power failure detection function and a power failure detection device installed in the lighting fixture. By deploying a storage battery built into the receiving device and the lighting equipment, it is possible to function as a lighting equipment in normal times by a simple method without the need for special construction work, and in an emergency, the storage battery installed in the lighting equipment can be used. provides a lighting fixture that functions as a disaster prevention light that lights up for a long time with the electric power of 1, and can be operated by a remote controller, such as dimming the light source, regardless of whether it is normal or in an emergency, and a power failure detection device for it. be.

In order to achieve the above object, the lighting fixture of the present invention includes:
A main body that can be attached to the ceiling,
a light source arranged on the front side of the main body and composed of a substrate on which a plurality of LEDs are mounted;
a storage battery and a power supply device arranged in the main body;
A power failure signal receiving unit that receives a power failure detection signal transmitted from a power failure detection device and transmits the power failure detection signal to the power supply device;
a remote control signal processing unit that receives an operation signal transmitted from a remote controller and transmits an operation signal of the light source to the power supply device;
A lighting fixture comprising
The power supply device is electrically connected to a commercial power supply to supply power to the light source and the storage battery,
Perform pairing with the power failure detection device,
supplying power from the storage battery to the light source based on the power failure detection signal;
operating the light source based on the operation signal;
It is characterized by

According to the present invention, a storage battery is built into a lighting fixture that is used by being attached to a fixture (wiring fixture) installed on the ceiling (fixture mounting surface), and a power failure detection installed in a power outlet during a power failure of a commercial power supply or the like. The signal transmitted from the device is received by the receiving device installed in the lighting equipment, and in the event of a power failure such as a commercial power supply, the lighting equipment is lit by the DC output of the storage battery, and the lighting equipment functions as an emergency light that can be lit for a long time. can be made

It is a side view which shows the whole lighting fixture which concerns on embodiment. It is an expansion perspective view of the whole lighting fixture concerning an embodiment. It is a top view which shows the state which removed the shade from the lighting fixture which concerns on embodiment. It is a perspective view which shows the state which removed the shade and the transparent cover from the lighting fixture which concerns on embodiment. It is a rear view of the lighting fixture which concerns on embodiment. It is a schematic sectional drawing of the main body of the lighting fixture which concerns on embodiment. It is a top view which shows the state which removed the lighting device cover of the lighting fixture which concerns on embodiment. It is a top view which shows the state which removed the power supply cover of the lighting fixture which concerns on embodiment. It is a perspective view which shows the state which removed the power supply cover of the lighting fixture which concerns on embodiment. (A) A plan view of the substrate with the LED according to the embodiment mounted, (B) the same side view, (C) a plan view showing the state in which the substrates are combined, (D) the same side view (B) 2 is a cross-sectional view of a main portion A of FIG. 2, and (E) is a perspective view of the lens of FIG. (A) Top view of the power failure detection device according to the embodiment, (B) is the same front view, (C) is the same right side view, (D) is the same rear view, (E) is the power failure detection device from above It is a perspective view seen. It is a schematic explanatory drawing of the operation|movement procedure of the lighting fixture which concerns on embodiment. (A) A side view, (B) a top view, and (C) a bottom view of the mounting adapter used in the lighting fixture according to the embodiment.

In order to facilitate understanding of the present invention, an example of a lighting fixture 1 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8. FIG. A lighting fixture 1 according to an embodiment of the present invention is generally called an LED ceiling light, and is a lighting fixture that is attached to an installation surface such as a ceiling 5 for use.

It should be noted that the embodiments described below show one specific example of the present invention, so the arrangement, functions, numerical values, etc. of the components described in the embodiments are merely examples, and these should not be construed as limiting the scope of the present invention.
Also, some members such as wires and screws that constitute the lighting equipment are omitted for the sake of complicating the drawing.

(Embodiment)
FIG. 1 is a side view showing the entire lighting fixture 1 according to the embodiment.

In a general house, fixtures (wiring fixtures) 2 called a hook ceiling rosette, a hook ceiling body, a hook ceiling, a hook rosette, etc. are attached to an installation surface such as a ceiling 5 for attaching a lighting fixture such as a ceiling light. ing. A hook fitting 137 provided on a dedicated mounting adapter 133 attached to the lighting fixture 1 is electrically and mechanically connected to the mounting fixture 2, whereby the lighting fixture 1 is attached to an installation surface such as the ceiling 5, and the lighting fixture 1 is installed. Commercial power is supplied to the appliance 1 through indoor wiring.

As shown in FIG. 1, the luminaire 1 according to the embodiment is provided with a shade 90 on the front side of the main body 10 so as to cover the entire front side of the main body 10, like a general ceiling light. The main body 10 is held on the ceiling 5 by engaging the hook 137 of the mounting adapter 133 with the mounting fixture 2 provided on the installation surface such as the ceiling 5 . Four rectangular parallelepiped contact members 25 arranged on the ceiling surface side of the main body 10 are positioned between the main body 10 and the ceiling 5 to keep the main body 10 horizontal and stabilize it so that it does not wobble. The contact member 25 is made of a flexible sponge-like member such as urethane foam. Here, in a state where the lighting fixture 1 is installed on the ceiling 5, the ceiling 5 side centering on the lighting fixture 1 is referred to as the rear side, and the floor surface side from which light is emitted from the light source 30 is referred to as the front side (front side). ).

FIG. 2 is an exploded perspective view of the entire lighting fixture according to the embodiment. It consists of a shade 90, a protective cover 31, a lighting device cover 75, a substrate 40 mounted on the outer peripheries of the power source device 50 and the storage battery 69, and a main body 10 having contact members 25 arranged at four positions on the rear side, in this order from the front side. A luminaire 1 is shown. An opening 13 for inserting and arranging a mounting adapter 133 is formed in the central portion of the protective cover 31 from the main body 10 .

3A is a plan view showing a state in which the shade 90 is removed from the lighting fixture 1 according to the embodiment, and FIG. 3B is a perspective view showing a state in which the protective cover 31 is further removed from the state of FIG. 3A.

FIG. 3A shows a substantially circular transparent protective cover 31 that covers the entire surface on which the substrate 40 is mounted. The protective cover 31 protects fingers from accidentally touching the mounting surface (charged portion) of the substrate 40 when the shade 90 is removed, and also prevents foreign matter such as dust and insects from entering inside. have a role.

As shown in FIG. 3A, the protective cover 31 has outer peripheral edges 32 at three locations on the peripheral side of the main body 10 and inner peripheral edges 33 around the central opening 13 . The edge portions 32 and 33 are in contact with the flat portion 11 and the edge portion 17 of the main body 10, respectively, and are fixed to the hole portion 15 of the main body 10 through six hole portions 34 and three hole portions 35 by fixing means such as screws. be done. The protective cover 31 has substantially the same shape as the lighting device cover 75 so as to cover the lighting device cover 75 while maintaining a certain space between it and the substrate 40, and has the same shape as the opening 13 in the center. It has an opening 36 . The number of holes 34 and 35 for fixing the protective cover 31 and the main body 10 and the fixing means are arbitrary and are not limited to the embodiment.

Further, as shown in FIGS. 3A and 3B, a plurality of U-shaped substrates 40 are arranged in the circumferential direction of the main body 10 so as to surround the central opening 13 . The substrate 40 has a plurality of sets of LEDs 41 and lenses 45 mounted on the surface thereof, and is called a light source, a light source module, a light source unit, or the like. A doughnut-shaped lighting device cover 75 is attached around the opening 13 . The opening 80 of the lighting device cover 75 has substantially the same shape as the opening 13 of the main body 10 . Here, the aggregate of the substrates 40 , that is, the ring-shaped bottom portion 12 of the main body 10 on which the substrates 40 are mounted is referred to as the light source 30 .

3C is a rear view of main body 10. FIG. The main body 10 has an opening 13 in the center and is made of a substantially circular flat plate. A storage portion (recess) 18 that protrudes toward the back side is formed around the opening 13 on the rear surface (rear side) of the main body 10 . The power supply device 50 and the storage battery 69 are housed in.

An indicator 51 is arranged on the side surface of the edge portion 19 formed around the main body 10 . The indicator 51 is made up of a light-emitting element such as an LED, and indicates the state of charge and remaining battery power of the storage battery 69 built into the main body 10 and also indicates the status of communication with the power failure detection device 150 . After the lighting equipment 1 is turned off, the indicator 51 is turned on for a certain period of time to display the remaining amount of the storage battery. In addition, the display of the remaining amount of the storage battery, etc. of the indicator 51 may continue without being turned off even after the lighting device 1 is turned off. The indicator 51 is not limited to the side surface of the edge portion 19 of the main body 10 and may be arranged at any visible position within the shade 90 of the main body 10 .

FIG. 3D is a schematic cross-sectional view of the main body 10 of the lighting fixture 1, and the upper side is the front (irradiation surface) side. An annular rim 17 is formed around the central opening 13 for fixing the mounting adapter 133 . A storage portion 18 for a power supply device 50 and the like is formed around the edge portion 17, and an annular bottom portion 12 is formed outside the storage portion 18 so as to protrude toward the front surface (light irradiation surface). . A plurality of substrates 40 are arranged on the front surface of the bottom portion 12 to form the light source 30 . In addition, the outermost peripheral portion of the main body 10 has an edge portion 19 standing on the front side along the outer periphery. A flat portion 11 is provided between the edge portion 19 and the bottom portion 12, and a holding portion 14 for detachably fixing the shade 90 is arranged.

FIG. 4A is a plan view showing a state in which the lighting device cover 75 of the lighting fixture 1 according to the embodiment is removed. In the annular housing portion 18 located on the outer periphery of the edge portion 17 surrounding the opening 13, a power supply device 50 covered by a substantially crescent-shaped power supply cover 76 and a storage battery 69 consisting of two battery packs 70 are placed in an annular shape. is stored in The surface of the power supply cover 76 includes a hemispherical sensor cover 56 covering the light receiving surface of the remote control light receiving sensor 55, an antenna cover 66 protruding in a dome shape, and a circular hole 59 formed in the surface of the power supply cover 76. A pairing switch 60 inserted through is arranged. The power supply cover 76 is fixed to the main body 10 by fixing means such as screws. The power supply cover 76 is formed by molding a metal plate into a half-moon shape, and the hemispherical sensor cover 56 and the antenna cover 66 arranged on the surface are both made of plastic.

4B is a plan view showing a state in which the power supply cover 76 is further removed from FIG. 4A, and FIG. 4C is a perspective view of the same. A remote control light receiving sensor 55 and an antenna 67 are arranged above the power supply device 50 . The remote control light receiving sensor 55 has a remote control signal processing unit that processes an operation signal (infrared signal) of the lighting fixture 1 transmitted from the external remote controller 100 and transmits an operation signal of the light source 30 to the power supply device 50 . Further, the antenna 67 has a power failure signal receiver, is connected to the power supply device 50, and communicates with the power failure detection device 150 by radio signals. The pairing switch 60 is a start switch for pairing the lighting fixture 1 and the power failure detection device 150 in a one-to-one (unique) relationship.

The power supply device 50 is electrically connected to the mounting adapter 133, receives power from the commercial power supply, and converts the commercial power supply into an appropriate direct current. A light source processing unit that controls dimming of the light source 30, a storage battery control unit that controls the input/output of the power supply of the storage battery 69, and a power failure detection signal sent from the power failure detection device 150 in response to the transmission of the operation signal. A power failure signal processing unit that receives and transmits signals to the light source processing unit and the storage battery control unit, a pairing processing unit that pairs the power failure detection device 150 and the power supply device 50 by a pairing signal from the power failure detection device 150, and a pair An indicator control unit is provided for controlling an indicator 51 that displays the ring connection state, the charging state of the storage battery, and the like.

As shown in FIG. 4C, the two battery packs 70 each consist of a pair of rechargeable batteries 72 in the form of cylindrical dry batteries. Each battery pack 70 is connected in series, and terminals 73 and 74 at both ends of the battery pack 70 are connected to the power supply device 50 respectively. The power supply device 50 supplies power to the storage battery 69, and stops supplying power when charging is completed. A storage battery 69 made up of two battery packs 70 stands by in a fully charged state in preparation for a power outage.

In general, emergency lights stipulated by the Electrical Appliance and Material Safety Law and certified by the Japan Lighting Manufacturers Association use JIS standard nickel-metal hydride batteries (Ni-MH) as storage batteries, which do not require a control circuit and are inexpensive, but they can be charged at all times. A dedicated circuit is required, and the standard for replacement is as short as 4 to 6 years.
As the rechargeable battery 72, for example, a lithium iron phosphate battery is used. Among lithium-ion batteries, this battery is characterized by being resistant to overcharge/overdischarge and having a long life.

The continuous lighting time of the light source 30 in the lighting fixture 1 of the present invention is designed, for example, so that the luminous flux of the light source 30 lasts for about 10 hours at 800 lumens. Also, if the luminous flux is reduced to about 150 to 500 lumens, continuous lighting for a longer time can be expected. This luminous flux can be adjusted with the operation switch 101 of the remote controller 100 .

5A is a plan view of a substrate 40 on which an LED 41 according to the embodiment is mounted, FIG. 5B is a side view of the same, and FIG. 5C is a state in which two substrates 40 are combined. FIG. 1D is a cross-sectional view of the main part of FIG.

FIG. 5A shows a plan view of a substrate 40 having an approximately U-shaped substrate 40 on which an LED 41 having a substantially hemispherical lens 45 is mounted. In the embodiment, 16 LEDs 41 are mounted on each substrate 40 along the edge of the substrate 40 . The substrate 40 has three holes 42 through which fixing members such as screws for fixing the substrate 40 to the main body 10 are passed.

FIG. 5B is a side view of the substrate 40 on which the LED 41 having the lens 45 is mounted. FIG. 5(D) shows an enlarged cross-sectional view of the portion surrounded by a circle A in FIG.

As shown in FIG. 5C, the surface of the substrate 40 is provided with a central point 48 and a plurality of black spots 49 at three locations around it. The center point 48 is a mark for determining the mounting position of the LED 41 mounted on the surface of the substrate 40, and the black dot 49 is a mark for adhesively fixing the leg portion 46 of the lens 45. FIG. The LED 41 is of surface mount (SMD) type and is soldered onto the center point 48 on the surface of the substrate 40 and the leg 46 of the lens 45 is glued onto the black spot 49 on the surface of the substrate 40 .

Also, as shown in FIG. 5(C), the substrate 40 can be formed into two substantially U-shaped substrates by cutting a substantially rectangular substrate into substantially U-shaped substrates. By making the substrate 40 substantially U-shaped in this manner, a large number of substrates 40 can be cut out with little loss of raw materials. Furthermore, by directly placing the substrate 40 on the surface of the main body 10, it is easy to change the layout of the substrate 40 according to the number of tatami mats and the amount of light required for lighting, and it is possible to respond immediately according to demand. .
In addition, since the substrate 40 is in direct contact with the main body 10 , the heat generated from the substrate 40 can be efficiently radiated through the main body 10 .

5(D) and 5(E), the lens 45 has three legs 46 on its bottom surface, a hemispherical space 47 near the center of the bottom surface for receiving the LED 41, and a reverse tapered shape on the top. recesses are provided. The light emitted from the LED 41 is diffused widely and evenly by the action of the lens 45, which has a shape that becomes thicker in the peripheral direction. , uniform diffusion and anti-glare properties are imparted.

As shown in FIG. 5D, a slight gap is provided between the lens 45 drilled in the substrate 40 and the substrate 40. Heat generated by the LED 41 is radiated through this gap, and the lens 45 Together with heat dissipation from the substrate 40, overheating of the LED 41 can be prevented.

The substrate 40 arranged as the light source 30 and the front surface (irradiation surface) side of the main body 10 on which the substrate 40 is arranged are coated with white paint or the like. By applying white paint to the surface, the irradiation light emitted by the LED 41 can be efficiently reflected toward the front side of the lighting fixture 1 .

In the embodiment, 16 LEDs 41 are surface-mounted along the edge of the substrate 40 per substrate 40, and the total number of the light sources 30 of the lighting device 1 includes 6 substrates 40 and 96 LEDs 41. An LED 41 is mounted. The number and arrangement of the LEDs 41 mounted on one substrate 40 and the number and arrangement of the substrates 40 constituting the light source 30 can be appropriately changed depending on the amount of light required for the object to be illuminated, the number of tatami mats, the application, and the like.

6(A) is a top view of the power failure detection device 150 according to the embodiment, (B) is a front view of the same, (C) is a right side view of the same, (D) is a rear view of the same, and (E) is a power failure detection 2 is a perspective view of the device 150 as seen from above; FIG.

The power failure detection device 150 is installed by being inserted into a power outlet 121 provided on an indoor wall or the like, and constantly monitors interruption of a commercial power supply or the like. The power failure detection device 150 has a substantially rectangular box-shaped housing, and is provided with a rod terminal (input terminal) 151 on the back side thereof, which is plugged into a power outlet 121 installed on a wall or the like to be energized. A pairing button 155 for pairing with the lighting device 1 and an indicator 156 for displaying an active state are arranged on the front surface of the housing. In addition, inside the housing, a signal control unit that detects a power failure due to interruption of commercial power supply and transmits a power failure detection signal, performs pairing with the power supply device 50, and an indicator control unit that controls the display state of the indicator 156 department is provided.

The indicator 156, for example, flashes a red LED display when pairing with the lighting device 1 is in a pairing standby state or in a disconnection state, and blinks a yellow LED when pairing is being authenticated. 1 is in a pairing connection state, it is indicated by a lighting state of the green LED.

As shown in FIG. 7, when a power supply such as a commercial power supply is cut off due to an earthquake or the like and a power failure occurs, the power supply to the power failure detection device 150 installed in the power outlet 121 is cut off. The power failure detection device 150 immediately transmits a power failure detection signal to the antenna 67 of the lighting fixture 1, and the antenna 67 includes a power failure signal receiving unit that receives the power failure detection signal transmitted from the power failure detection device. , a power failure detection signal is transmitted to the power failure signal processing unit of the power supply device 50 . Upon receiving the power failure detection signal, the power failure signal processing unit transmits a signal to the light source processing unit and the storage battery control unit, power supply from the storage battery 69 is started, and emergency lighting by the light source 30 is started.
The lighting state (emergency lighting) is maintained until a commercial power supply recovery signal is transmitted from the power failure detection device 150 .

Here, pairing between the lighting device 1 and the power failure detection device 150 will be described. A pairing switch 60 is arranged on the upper surface of the lighting device cover 75 of the main body 10 of the lighting device 1 , and the power failure detection device 150 is provided with a push-button pairing button 155 . For pairing, the ID of the power failure detection device 150 is transmitted to the lighting device 1 by pressing the pairing button 155 of the power failure detection device 150 and then pressing the pairing switch 60 of the main body 10 of the lighting device 1. 1 side confirms the ID, and the ID of the lighting fixture 1 is returned to the power failure detection device 150 . Next, after confirming by the indicator 156 that the ID of the lighting device 1 has been returned on the side of the power failure detection device 150, the pairing button 155 is pushed down to mutually authenticate and store the IDs. A one-to-one pairing authentication with sensing device 150 is established. The authentication for pairing may be performed by transmitting a pairing signal from the lighting device 1 side to the power failure detection device 150 to perform mutual authentication, contrary to the above procedure.

Further, the lighting fixture 1 and the power failure detection device 150 may be paired and connected in advance in a one-to-one relationship before shipping the product. In this case, by installing the lighting fixture 1 and inserting the power failure detection device 150 into the power outlet 121, the pairing connection can be established immediately without conducting the energization operation by pressing down the pairing switch 60 of the lighting fixture 1. .

When the lighting fixture 1 and the power failure detection device 150 are paired and connected, the lighting fixture 1 side always transmits radio waves at a cycle of about 3 to 4 times per minute, and the pairing connection state is established. to confirm. When there is no response from the power failure detection device 150, such as when the power failure detection device 150 is disconnected from the power outlet 121, it is determined that the pairing connection is broken, and the indicator 51 installed in the lighting fixture 1 The user is warned of an abnormal situation by blinking an LED or the like. A warning of an abnormal situation may be given by a buzzer or voice in addition to the display of the indicator 51 . In addition, when the power failure detection device 150 is not disconnected from the power outlet 121 and the pairing connection is broken, in addition to the abnormality display by the indicator 51 of the lighting fixture 1, the abnormality display by the indicator 156 of the power failure detection device 150 Confirmation is possible.

Wireless communication between the lighting fixture 1 and the power failure detection device 150 uses a frequency band assigned to a weak radio station of 315 MHz to 1 GHz specified in the Radio Law, but preferably a frequency band of 320 MHz or less where relatively strong radio waves can be used. should be used.

The shade 90 shown in FIG. 1 is detachably attached so as to cover the entire front surface of the main body 10 including the substrate 40 and the protective cover 31 . The shade 90 is formed of translucent acrylic resin, polycarbonate resin, or the like having diffusivity such as milky white, and is formed in a hollow circular shape having an opening on one side. The shade 90 is a member having a function of efficiently diffusing the light emitted from the light source 30, and is called a globe, a cover, or the like. A holding portion 14 is provided on the flat portion 11 of the main body 10, and the edge portion (not shown) of the shade 90 is engaged with the holding portion 14 of the main body 10, so that the shade 90 is detachably held on the main body 10. be done.

FIG. 8 shows a mounting adapter 133 which is an attachment for mounting the main body 10 to the fixture 2 of the ceiling 5. As shown in FIG. The mounting adapter 133 is a substantially cylindrical member having a pair of hook fittings 137 on the top surface, two claws 135 on both side surfaces, and a pair of release levers 138 and 139 on the bottom surface. The hook fittings 137 of the mounting adapter 133 are mechanically connected by fitting into a pair of engaging grooves provided in the mounting fixture 2 arranged on the ceiling 5, and are electrically connected to the commercial power supply through the power cord 136. Connecting.

The claw 135 is a member for engaging the mounting adapter 133 with the edge 17 provided in the opening 13 of the lighting fixture 1 to fix the mounting adapter 133 to the main body 10 . Also, by drawing the pair of release levers 138 and 139 together, the claw 135 can be drawn into the mounting adapter 133 and the mounting adapter 133 can be removed from the mounting fixture 2 .

Here, a method for attaching the lighting device 1 to the fixture 2 will be described. First, the mounting adapter 133 is attached to the fixture 2 . Next, the main body 10 of the lighting device 1 is held, and the mounting adapter 133 is inserted through the opening 13 provided in the main body 10 . When the main body 10 is lifted so as to push up the claw 135 of the mounting adapter 133 from below, the claw 135 is pushed into the mounting adapter 133 by the inner edge portion 17 provided on the main body 10 . When the main body 10 is lifted up in this state, the claw 135 climbs over the edge 17 and the claw 135 is positioned under the edge 17 . Since the claw 135 is biased outward from the mounting adapter 133, it projects outward again and supports the main body 10 from below. After that, the shade 90 is aligned with a mark (not shown) inside the edge portion 17 of the main body 10, the shade 90 is aligned with the inside of the main body 10, the shade 90 is lifted horizontally, and is pressed against the main body 10 so as to be in close contact with the shade. By rotating the 90 to the right (clockwise) until it clicks and locks, the locking portions (not shown) provided on the shade 90 are moved to the three holding portions provided on the flat portion 11 of the main body 10. 14 to retain the shade 90 on the body 10 .

To remove the main body 10 from the mounting adapter 133, after removing the shade 90 from the main body 10, release levers 138 and 139 provided on the bottom surface of the mounting adapter 133 are used. By pulling the release levers 138 and 139 inward, the claw 135 is retracted into the mounting adapter 133 , the engagement with the edge 17 is released, and the main body 10 is removed from the mounting adapter 133 .

Lighting/lighting of the luminaire 1 is normally performed by powering on/off the wall switch 120 or operating the operation switch 101 of the remote controller 100 . Light control such as turning on, turning off, dimming, and increasing brightness of the light source 30 can be performed by operating the remote controller 100 in both normal and emergency lighting. For example, when the lighting device 1 is turned off due to a power failure or the like and emergency lighting is started, there may be cases where it is not necessary to turn on the lighting device 1 because it is daytime and the room is bright. In such a case, by operating the operation switch 101 of the remote controller 100, the light source 30 of the lighting fixture 1 can be dimmed or turned off to prevent unnecessary consumption of the storage battery 69 and prepare for lighting at night. can. This operation is particularly effective when the power outage lasts for a long period of time.
Furthermore, the dimming function by operating the remote controller 100 may be achieved by providing a dimming switch (not shown) on the main body 10 of the lighting fixture 1 and by operating the dimming switch.

As shown in FIG. 7, the remote controller 100 outputs an infrared signal indicating the contents (control contents of how to control the lighting fixture 1) instructed by the user's operation, and controls the lighting fixture 1. The light is received by the light receiving sensor 55 . The infrared signal may be, for example, a signal indicating an IR (Infrared) code indicating control details. The remote controller 100 outputs an infrared signal indicating the content of control of the lighting fixture 1 by outputting an infrared signal indicating an IR code corresponding to the content of the operation. The remote controller 100 is provided with an operation switch 101 . The operation switch 101 is used to turn off, turn on, dim, or increase the brightness of the lighting fixture 1 .

The LEDs 41 mounted on the light source 30 in the lighting fixture 1 according to the embodiment may be suitably a daylight white LED, a light bulb color LED, a daylight color LED, or the like. An LED (“Fire Look” (registered trademark) may be provided. In this case, the light bulb color LED and the daylight color LED are LEDs that emit light in light bulb color and daylight color, respectively. For example, an LED that lights green for several minutes as time and afterglow In the above case, it is basic that the light bulb color LED and the daylight color LED are alternately arranged on the surface of the substrate 40, but they are not necessarily alternate. The arrangement state can be adjusted as necessary, and the firefly look LEDs may be arranged at appropriate locations on the substrate 40 .
Further, by providing a color tone switch (not shown) on the main body 10 of the lighting fixture 1, the color may be adjusted on the main body 10 side.

When various LEDs as described above are mounted, the remote controller 100 is equipped with an operation switch 101 for operating lighting, extinguishing, dimming, and increasing brightness of the lighting fixture 1, as well as a light bulb color, daylight white, daylight color, and the like. By providing a color switch, a night light switch for turning on/off the night light, and the like, it is possible to control the lighting color emitted by the light source 30, for example.

Furthermore, by providing the remote controller 100 with a pairing operation button for instructing pairing connection between the lighting device 1 and the power failure detection device 150, the pairing switch 60 of the lighting device 1 or the power failure detection device 150 can be paired. Pairing connection may be established using the remote controller 100 without operating the button 155 .

Wireless communication between the remote controller 100 and the remote control light receiving sensor 55 can be performed using infrared signals, 2.4 GHz specific low-power radio, other frequency domain radio, ZigBee (registered trademark), Bluetooth (registered trademark), Wi-Fi ( registered trademark), infrared communication, or the like may be used.

Furthermore, various sensors such as an illuminance sensor for detecting brightness, a motion sensor for detecting movement of a person, a color sensor, and the like may be provided in the light source 30 of the lighting device 1 . As a result, when the lighting apparatus 1 is turned on in an emergency due to an earthquake or the like, for example, (1) the emergency lighting will not be turned on when the room is bright even if a power failure occurs, (2) the light will be turned off when the room becomes bright in the morning, and (3). It is possible to add functions such as turning off the light when there is no one, (4) switching to night light when the futon is spread, etc. It is possible to aim at efficient operation of the lighting fixture 1 containing.

The present invention is not limited to the above embodiments, and various modifications and applications can be made to the above embodiments.

In this way, the present invention provides a lighting fixture with a power failure detection function such as a ceiling light using an LED as a light source, in which a storage battery and a power supply device are arranged in the lighting fixture, and a power failure detection device is connected to a power outlet to which commercial power is supplied. To provide a lighting fixture which normally functions as a lighting fixture and functions as a disaster prevention light (emergency light) which lights for a certain period of time in an emergency such as a power failure, by a simple method.

1 lighting fixture 2 fixture 5 ceiling (fixture mounting surface)
REFERENCE SIGNS LIST 10 Main body 11 Plane portion 12 Bottom portion 13, 36, 80 Opening 14 Holding portion 15 Hole 17 Edge 18 Storage portion (recess)
19 edge 25 contact member 30 light source 31 protective cover 32 (outer circumference) edge 33 (inner circumference) edge 34 (outer circumference) hole 35 (inner circumference) hole 40 substrate 41 LED
42 hole 45 lens 46 leg 47 space 48 center point 49 black dot 50 power supply device 51 indicator 55 remote control light receiving sensor 56 sensor cover 59 hole 60 pairing switch 66 antenna cover 67 antenna 69 storage battery 70 battery pack 72 rechargeable battery 73, 74 terminal 75 lighting device cover 76 power supply cover 90 shade 100 remote controller 101 operation switch 120 wall switch 121 power outlet 133 mounting adapter 135 claw (holding member)
136 power cord 137 hook metal fittings 138, 139 release lever 150 power failure detection device 151 bar terminal (input terminal)
155 Pairing Button 156 Indicator

Claims (6)

A main body that can be attached to the ceiling,
a light source arranged on the front side of the main body and composed of a substrate on which a plurality of LEDs are mounted;
a storage battery and a power supply device arranged in the main body;
A power failure signal receiving unit that receives a power failure detection signal transmitted from a power failure detection device and transmits the power failure detection signal to the power supply device;
a remote control signal processing unit that receives an operation signal transmitted from a remote controller and transmits an operation signal of the light source to the power supply device;
A lighting fixture comprising
The power supply device is electrically connected to a commercial power supply to supply power to the light source and the storage battery,
Perform pairing with the power failure detection device,
supplying power from the storage battery to the light source based on the power failure detection signal;
operating the light source based on the operation signal;
A lighting fixture characterized by: the body has an opening in the center,
a mounting adapter that is inserted into the opening, is attached to a mounting fixture that is mounted on the ceiling, is electrically and mechanically connected to the mounting fixture, and is electrically connected to the power supply device;
A pairing switch arranged on the upper part of the power supply device for pairing the power supply device and the power failure detection device;
a shade that covers the entire surface of the front side of the main body;
2. The luminaire according to claim 1, comprising: The power supply device covered with a power supply cover and the storage battery are arranged around the opening on the inner peripheral side of the light source,
a lighting device cover covering the power supply cover and the storage battery and having an opening in the center;
3. The luminaire according to claim 1, further comprising a protective cover having an opening in the center covering the front surface of the light source and the lighting device cover. The substrate is a substantially U-shaped flat plate on which the plurality of LEDs are mounted,
the plurality of substrates of the light source are arranged on the front side of the main body in a substantially circular shape around the opening;
4. A lighting fixture according to any one of claims 1 to 3, wherein each LED is provided with a substantially semicircular lens for diffusing emitted light on the light emitting surface side. 5. The power supply device according to any one of claims 1 to 4, characterized in that the power supply device is covered with the power supply cover having a substantially half-moon shape, and is housed in a circular recess surrounding the opening of the main body together with the storage battery. Luminaire as described. The power failure detection device is
a substantially rectangular parallelepiped housing;
an input terminal arranged on the back of the housing and inserted into an outlet connected to a commercial power supply;
a pairing button arranged on the front surface of the housing for pairing with the power supply device of the lighting fixture;
An indicator that is arranged near the pairing button and displays the active state of the power failure detection device;
A signal control unit that is arranged inside the housing, detects a power failure due to interruption of the commercial power supply, transmits the power failure detection signal, and performs pairing with the power supply device. Item 6. The lighting fixture according to any one of Items 1 to 5.

Images