JP6830195B2 - lighting equipment - Google Patents

Description

The present invention relates to a ceiling-embedded luminaire.

Conventionally, lighting fixtures such as ceiling lights installed on a ceiling surface are known (for example, Patent Document 1). The ceiling light is, for example, a light source module that emits illumination light, an instrument body to which the light source module is attached, a power supply unit housed in the instrument body, and a translucency attached to the instrument body so as to cover the light source module. Equipped with gloves.

On the other hand, ceiling-embedded lighting fixtures such as downlights embedded in the ceiling are known (for example, Patent Document 2). The ceiling-embedded luminaire includes a lamp unit attached to the opening of the ceiling and a power supply unit arranged behind the ceiling. The lamp unit includes, for example, a fixture main body to which a light source module is attached, and a frame body portion for holding the fixture main body in an opening in the ceiling.

In a luminaire, the light source module is composed of, for example, an LED (Light Emitting Diode). In this case, the power supply unit generates electric power for causing the light source module to emit light by converting AC electric power from a commercial power source into DC electric power. The electric power generated by the power supply unit is supplied to the light source module via an electric wire.

Japanese Unexamined Patent Publication No. 2012-146666 Japanese Unexamined Patent Publication No. 2008-31238

In recent years, as lighting fixtures such as ceiling lights, those having a wireless communication function have been proposed. Ceiling lights with a wireless communication function are equipped with a wireless antenna for wireless communication and a wireless communication module in the power supply unit housed in the main body of the appliance, and by receiving wireless signals with the wireless antenna for wireless communication. , Lighting equipment is controlled. For example, by operating the wireless remote controller, the user can perform pairing between the wireless remote controller and the luminaire, or group a plurality of luminaires.

Further, as a lighting fixture such as a ceiling light, one having an infrared communication function is known. A luminaire having an infrared communication function includes an infrared communication module having an infrared receiver, and the luminaire is controlled by the infrared receiver receiving an infrared signal. For example, by operating the infrared remote controller, the user can control the turning on and off of the lighting equipment, and control the dimming or toning of the lighting equipment.

However, unlike ceiling lights, ceiling-embedded lighting fixtures such as downlights cannot perform both wireless communication and infrared communication because the power supply unit is located behind the ceiling.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a ceiling-embedded lighting fixture capable of performing both wireless communication and infrared communication.

In order to achieve the above object, one aspect of the luminaire according to the present invention is a ceiling-embedded luminaire, which has a light source portion embedded in an opening of the ceiling to emit illumination light. The lighting equipment unit includes a lighting equipment unit and a power supply unit that is arranged behind the ceiling and generates power for causing the light source unit to emit light, and the lighting equipment unit is configured to be able to change the attitude of the light source unit with respect to the ceiling surface. The lamp unit has an infrared communication module that receives an infrared signal for controlling the luminaire, and the power supply unit has a radio communication module that receives a radio signal for controlling the luminaire.

According to the present invention, it is possible to realize a ceiling-embedded lighting fixture capable of performing both wireless communication and infrared communication.

It is sectional drawing which shows typically the luminaire according to embodiment which was embedded and arranged in the ceiling. It is a perspective view of the lamp unit in the lighting equipment which concerns on embodiment. It is a perspective view of the lamp unit in the lighting equipment which concerns on embodiment. It is sectional drawing of the lamp unit in the lighting equipment which concerns on embodiment. It is an exploded view of the infrared communication module used for the lighting equipment which concerns on embodiment. It is a figure for demonstrating the rotation operation of the lamp unit in the luminaire which concerns on embodiment. It is sectional drawing of the lighting fixture unit in the lighting fixture which concerns on modification 1 of embodiment. It is sectional drawing of the lamp unit in the lighting equipment which concerns on modification 2 of embodiment. It is sectional drawing of the lamp unit in the lighting equipment which concerns on the modification 3 of embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, all the embodiments described below show a preferable specific example of the present invention. Therefore, the numerical values, shapes, materials, components, arrangement positions of the components, connection forms, etc. shown in the following embodiments are examples and are not intended to limit the present invention. Therefore, among the components in the following embodiments, the components not described in the independent claims indicating the highest level concept of the present invention will be described as arbitrary components.

Further, each figure is a schematic view and is not necessarily exactly illustrated. In each figure, substantially the same configuration is designated by the same reference numerals, and duplicate description may be omitted or simplified.

In the present specification and drawings, the X-axis, the Y-axis, and the Z-axis represent the three axes of the three-dimensional Cartesian coordinate system. In the present embodiment, the Z-axis direction is the vertical direction and is perpendicular to the Z-axis. (Direction parallel to the XY plane) is the horizontal direction. The X-axis and the Y-axis are orthogonal to each other and both are orthogonal to the Z-axis.

(Embodiment)
First, the schematic configuration of the luminaire 1 according to the embodiment will be described with reference to FIG. FIG. 1 is a cross-sectional view schematically showing a lighting fixture 1 according to an embodiment embedded in a ceiling 2.

As shown in FIG. 1, the luminaire 1 is a ceiling-embedded luminaire such as a downlight, and is embedded in the ceiling 2 of a building to irradiate the illuminating light downward (floor or the like).

The luminaire 1 includes a lamp unit 100 having a light source unit 111 and a power supply unit 200 having a power supply circuit 210. In the present embodiment, the lamp unit 100 and the power supply unit 200 are structurally separated and are installed at different locations on the ceiling 2.

Specifically, the lamp unit 100 is embedded and arranged in the opening 2a of the ceiling 2, and the power supply unit 200 is arranged on the back surface (behind the ceiling) of the ceiling 2. The opening 2a of the ceiling 2 is a mounting hole for mounting the lamp unit 100 to the ceiling 2. The opening 2a is a through hole penetrating the ceiling 2, for example, a circular hole having a circular opening.

The lamp unit 100 is a lamp body having a light source unit 111, and emits illumination light. Further, the lamp unit 100 has an infrared communication module 101 that receives an infrared signal (infrared light). The infrared communication module 101 receives an infrared signal for controlling the luminaire 1. The wavelength of the infrared signal is, for example, 945 nm, but is not limited to this. The infrared signal is transmitted from, for example, an infrared remote controller 3 having an infrared transmission function. That is, both the lamp unit 100 and the infrared remote controller 3 have an infrared communication function.

The infrared remote controller 3 that performs infrared communication with the infrared communication module 101 is operated by the user. When the user operates the infrared remote controller 3, the infrared remote controller 3 transmits an infrared signal for controlling the lighting fixture 1.

In the present embodiment, for example, the infrared remote controller 3 transmits an infrared signal (infrared signal for individual lighting control) for controlling the illumination mode of the illumination light emitted from the lamp unit 100 (light source unit 111). In this case, the infrared communication module 101 of the lighting fixture 1 receives an infrared signal (infrared signal for individual lighting control) for controlling the illumination mode of the illumination light of the light source unit 111 as an infrared signal for controlling the lighting fixture 1. Receive.

Specifically, when the user operates the infrared remote controller 3 to transmit an infrared signal for lighting control to the luminaire 1, the lighting fixture 1 can be turned on and off, or the luminaire 1 can be dimmed or dimmed. You can control it. That is, the user operates the infrared remote controller 3 when he / she wants to individually control one lighting fixture 1. As a result, from the infrared remote control 3, an infrared signal for controlling the turning on and off of the lamp unit 100 (light source unit 111), or dimming control or color adjustment control of the lamp unit 100 (light source unit 111) can be performed. An infrared signal such as an infrared signal is transmitted.

Further, an infrared signal (infrared signal for pairing) for pairing the lighting fixture 1 and the wireless remote controller 4 is also transmitted from the infrared remote controller 3. In this case, the infrared communication module 101 of the luminaire 1 receives an infrared signal (infrared signal for pairing) for associating the luminaire 1 with the wireless remote controller 4 as an infrared signal for controlling the luminaire 1.

The infrared communication module 101 and the power supply unit 200 are connected by a first electric wire 310 such as a signal cable (control line), and the infrared signal received by the infrared communication module 101 is used as a control signal via the first electric wire 310. Is transmitted to the power supply unit 200. That is, the first electric wire 310 transmits a control signal corresponding to the infrared signal received by the infrared communication module 101 to the power supply unit 200. The first electric wire 310 is, for example, a control line for a signal cable or the like.

The power supply unit 200 has a wireless communication module 201 that receives a wireless signal. The wireless communication module 201 receives a wireless signal for controlling the lighting fixture 1. The wireless communication module 201 has a wireless antenna for receiving the wireless signal and a processing circuit (IC) for processing the wireless signal received by the wireless antenna. The wireless antenna is, for example, a pattern antenna provided on a substrate. The wireless signal received by the wireless antenna is converted into a predetermined control signal (electrical signal) by the processing circuit and output to the control circuit 220 of the power supply unit 200. The frequency of the wireless signal received by the wireless communication module 201 is the UHF band, and is not limited to the 920 MHz band as an example.

The wireless signal received by the wireless communication module 201 is transmitted from, for example, a wireless remote controller (radio wave remote controller) 4 having a wireless transmission function. The wireless remote controller 4 may be a mobile terminal, but may be mounted on a wall or the like. The wireless remote controller 4 is installed on a wall in the room, for example, and performs various controls on one or a plurality of lighting fixtures 1 installed in the room.

The wireless remote controller 4 that performs wireless communication with the wireless communication module 201 is operated by the user. When the user operates the wireless remote controller 4, the wireless remote controller 4 transmits a wireless signal for controlling the lighting fixture 1.

In the present embodiment, the wireless remote controller 4 transmits a wireless signal (pairing wireless signal) for pairing the wireless remote controller 4 with the lighting fixture 1. In this case, the wireless communication module 201 of the luminaire 1 receives a wireless signal (pairing wireless signal) for associating the wireless remote controller 4 with the luminaire 1 as a wireless signal for controlling the luminaire 1. To do.

Further, from the wireless remote controller 4, a wireless signal (collective lighting control) for simultaneously controlling a plurality of luminaires 1 belonging to this one group with a plurality of luminaires 1 paired with the wireless remote controller 4 as one group. Radio signal) is also transmitted. In this case, the wireless communication module 201 of the lighting fixture 1 uses a plurality of lighting fixtures 1 (a plurality of lighting fixtures 1 in one group) paired with the wireless remote control 4 as wireless signals for controlling the lighting fixture 1. Receives a wireless signal for simultaneous control (wireless signal for batch lighting control).

Here, an example of a case where the lighting fixture 1 is controlled by using the infrared remote controller 3 and the wireless remote controller 4 will be described. In particular, the pairing setting method will be described.

First, the wireless remote controller 4 is operated to put the wireless remote controller 4 into the pairing mode, and the wireless remote controller 4 transmits a pairing wireless signal to the luminaire 1. As a result, the wireless communication module 201 of the lighting fixture 1 receives the pairing wireless signal from the wireless remote controller 4. At this time, the luminaire 1 to be paired with the wireless remote controller 4 may be either one or a plurality of luminaires, and the luminaire 1 or the plurality of luminaires 1 that have received the pairing wireless signal is the wireless remote controller 4. Candidates to be paired.

Next, while the pairing wireless signal is being transmitted from the wireless remote controller 4, the infrared remote controller 3 is operated to send the pairing infrared signal to the specific lighting fixture 1 to be paired with the wireless remote controller 4. Send. The pairing infrared signal transmitted from the infrared remote controller 3 is received by the infrared communication module 101 of the lighting fixture 1.

As a result, the specific luminaire 1 that has received the pairing infrared signal is paired with the wireless remote controller 4 that transmits the pairing wireless signal. Further, when pairing with a plurality of lighting fixtures 1, the infrared remote controller 3 corresponding to each lighting fixture 1 is sequentially operated to sequentially transmit an infrared signal for pairing to each of the plurality of lighting fixtures 1. This makes it possible to pair a specific one wireless remote controller 4 with a plurality of specific lighting fixtures 1.

Then, one or a plurality of specific lighting fixtures 1 paired with the specific wireless remote controller 4 are simultaneously controlled in the lighting mode by the collective lighting control wireless signal from the specific wireless remote controller 4. That is, when the pairing setting is completed, by operating one specific wireless remote controller 4, it is possible to simultaneously perform on / off control for a plurality of specific lighting fixtures 1 belonging to one paired group. Dimming control can be performed at the same time.

Further, even after the pairing with the plurality of lighting fixtures 1 is completed, it is possible to individually control the lighting mode of each lighting fixture 1 by operating the infrared remote controller 3 corresponding to each lighting fixture 1. ..

In the present embodiment, the wireless communication module 201 has only a function of receiving a wireless signal, but is not limited to this, and may have a function of transmitting a wireless signal. In this case, if the wireless remote controller 4 has a function of receiving the wireless signal, the wireless remote controller 4 can receive the wireless signal transmitted from the wireless communication module 201.

The power supply unit 200 has a power supply function for generating electric power for causing the light source unit 111 to emit light. Specifically, the power supply unit 200 converts the AC power from the commercial power supply supplied from the power supply terminal block 205 into DC power by the power supply circuit 210.

The power supply unit 200 and the lamp unit 100 (light source unit 111) are connected by a second electric wire 320, and the DC power generated by the power supply unit 200 is transmitted to the light source unit 111 of the lamp unit 100 via the second electric wire 320. Is supplied to. The second electric wire 320 is a power supply line such as a power cable.

Further, in the present embodiment, the power supply unit 200 further has a lighting control function for controlling the lighting mode of the lamp unit 100 (light source unit 111). Specifically, the power supply unit 200 controls the illumination mode (light emission mode) of the light source unit 111 according to the wireless signal received by the wireless communication module 201 or the infrared signal received by the infrared communication module 101 by the control circuit 220. .. For example, the power supply unit 200 can turn on or off the lamp unit 100 (light source unit 111), change the brightness of the lamp unit 100 (light source unit 111), or change the light color or color temperature by the control circuit 220. To do. In the present embodiment, the control circuit 220 is incorporated in the same circuit board together with the power supply circuit 210.

The power supply unit 200 has a wireless communication module 201 and a housing 202 that houses the wireless communication module 201. Further, the power supply unit 200 has a circuit board 203 and a plurality of circuit elements 204.

The housing 202 houses the wireless communication module 201 and the circuit board 203 on which a plurality of circuit elements 204 are mounted. For example, the housing 202 is a case made of metal or an insulating resin. In the present embodiment, the housing 202 is a metal case. The housing 202 is arranged behind the ceiling.

The circuit board 203 is a printed wiring board on which metal wiring having a predetermined shape is formed. A plurality of circuit elements 204 are mounted on the circuit board 203.

The plurality of circuit elements 204 include a power supply circuit element that constitutes a power supply circuit 210 that generates power for causing the light source unit 111 to emit light, and a control circuit element that constitutes a control circuit 220 that controls the illumination mode of the light source unit 111. Is included.

The power supply circuit element constituting the power supply circuit 210 and the control circuit element constituting the control circuit 220 include, for example, a capacitance element (electrolytic capacitor, ceramic capacitor, etc.), a resistance element (resistor, etc.), a rectifying circuit element, a coil element, and a transformer. , Noise filters, diodes, integrated circuit elements (ICs), semiconductor elements (FETs, etc.) and the like.

The power supply circuit 210 converts, for example, AC power from an external power source such as a commercial power source into DC power of a predetermined level by rectifying, smoothing, stepping down, or the like. The control circuit 220 is a dimming control circuit, a toning control circuit, and the like. The DC power output from the power supply circuit 210 is controlled by the control circuit 220.

Further, the power supply unit 200 is provided with a power supply terminal block 205. An electric wire such as a VVF cable is connected to the power terminal block 205, and AC power from a commercial power source is supplied to the power terminal block 205 by this electric wire. The AC power supplied to the power terminal block 205 is supplied to the power circuit 210.

In the lighting fixture 1 configured in this way, for example, when the infrared signal transmitted from the infrared remote control 3 is received (received) by the infrared communication module 101, the lighting fixture unit 100 (light source) according to the instruction content of the infrared signal. The unit 111) is turned on and off, the brightness of the lighting unit 100 (light source unit 111) is changed, and the light color and color temperature are changed.

In this case, when an infrared signal is received by the infrared communication module 101 mounted on the lamp unit 100, the infrared signal is converted into a predetermined control signal (electrical signal) by the infrared communication module 101 and is converted into a predetermined control signal (electrical signal) by the first electric wire 310. It is transmitted to the control circuit 220 of the power supply unit 200.

Then, the control signal based on the infrared signal transmitted from the infrared communication module 101 to the power supply unit 200 via the first electric wire 310 is processed by the control circuit 220 and the power supply circuit 210 to become a desired DC power, and the second It is supplied to the light source unit 111 of the lamp unit 100 via the electric wire 320. As a result, the light source unit 111 changes its illumination mode according to the instruction content of the infrared signal.

For example, when the infrared signal received by the infrared communication module 101 is a lighting signal or an extinguishing signal, the supply of DC power from the power supply unit 200 (power supply circuit 210) to the light source unit 111 is started or stopped. When the infrared signal received by the infrared communication module 101 is a dimming signal (PWM dimming signal or phase control dimming signal) or a toning signal, the dimming controlled or toning controlled DC power is the power supply circuit 210. Is supplied to the light source unit 111. As a result, the light source unit 111 is dimmed to change the brightness of the illumination light, or the light source unit 111 is toned to change the light color or the color temperature.

The same applies to the case where the remote controller 4 is operated to change the lighting mode of the luminaire 1 (when turning on / off control, dimming control, etc.).

[Lamp unit]
Next, the detailed configuration of the lamp unit 100 in the lighting fixture 1 according to the embodiment will be described in detail with reference to FIGS. 2 to 4. 2 and 3 are perspective views of the lamp unit 100 in the lighting fixture 1 according to the embodiment. FIG. 4 is a cross-sectional view of the lamp unit 100. Note that FIG. 4 shows only a cross-sectional portion of the lamp unit 100. Further, in FIGS. 2 to 4, the first electric wire 310 and the second electric wire 320 are omitted.

As shown in FIGS. 2 to 4, the lamp unit 100 has an instrument main body 110 having a light source unit 111 (see FIG. 4) and a frame body unit 120.

The lighting fixture 1 in the present embodiment is a universal type downlight, and the lighting fixture unit 100 has a ceiling 2 of the fixture main body 110 (light source unit 111) in order to change the irradiation direction of the illumination light of the light source unit 111. It is configured so that the posture of the ceiling surface 2b can be changed.

[Instrument body]
The fixture body 110 is a lamp body unit that emits illumination light by the light source unit 111. The instrument body 110 is supported by the frame body 120. In the present embodiment, the fixture main body 110 is rotated so that the angle formed by the optical axis of the light source unit 111 and the ceiling surface 2b of the ceiling 2 changes, and the frame is rotated horizontally with respect to the ceiling surface 2b. It is supported by the body 120.

In the present embodiment, the instrument main body 110 has a light source unit 111, a base 112, a reflector 113, and a lens 114.

[Light source]
The light source unit 111 shown in FIG. 4 is, for example, a light source module that irradiates white light as illumination light. In the present embodiment, the light source unit 111 is an LED module (LED light source) composed of LEDs. As an example, the light source unit 111 has a COB (Chip On Board) structure, and has a substrate, an LED mounted on the substrate, and a sealing member for sealing the LED. The LED and the sealing member serve as a light emitting unit of the light source unit 111.

The substrate is a mounting substrate for mounting an LED, and is, for example, a ceramic substrate, a resin substrate, a metal base substrate, or the like. The substrate is formed with a pair of electrode terminals for receiving DC power from the power supply unit 200, and a metal wiring having a predetermined pattern for electrically connecting the LEDs. A second electric wire 320 is connected to the pair of electrode terminals.

An LED is an example of a light emitting element, for example, a bare chip that emits a single color of visible light. Specifically, the LED is a blue LED chip that emits blue light when energized. A plurality of LEDs are arranged on a substrate in a matrix, for example. It is sufficient that at least one LED is arranged.

The sealing member is, for example, a translucent resin. The sealing member in the present embodiment contains a phosphor as a wavelength conversion material for wavelength conversion of light from an LED. 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 is a blue LED chip, for example, a YAG-based yellow phosphor can be used in order to obtain white light. In this case, the yellow phosphor absorbs a part of the blue light emitted by the blue LED chip and is excited to emit the yellow light. Then, the yellow light and the blue light not absorbed by the yellow phosphor are mixed to form white light, which is emitted from the light source unit 111.

The sealing member is formed in a circular shape so as to collectively seal all the LEDs, but a plurality of LEDs may be sealed in a line for each row, or each LED may be sealed one by one. It may be sealed individually.

Further, the light source unit 111 in the present embodiment is a light source module capable of performing dimming control and color matching control. Therefore, the light source unit 111 has, for example, a plurality of light emitting units having different light colors or color temperatures. In this case, the light color and color temperature of each light emitting unit can be made different by using LEDs having different light colors or by adjusting the type and amount of the wavelength conversion material (fluorescent material).

As shown in FIG. 4, the light source unit 111 configured in this way is attached to the base 112 by a holder. For example, the light source unit 111 can be arranged at a predetermined position on the base 112 by pressing the light source unit 111 against the base 112 by the holder and fixing the holder and the base 112 with screws or the like. Further, in the present embodiment, the light source unit 111 is arranged at the center of the optical axis of the lamp unit 100.

[Base]
The base 112 is an instrument body in which the light source unit 111 is arranged. The base 112 supports the light source unit 111 and also functions as a heat sink that dissipates heat generated by the light source unit 111. Therefore, it is preferable that the base 112 is made of a metal material such as aluminum or a material having high thermal conductivity such as a high thermal conductivity resin. In the present embodiment, the base 112 is made of die-cast aluminum.

As shown in FIG. 4, the base 112 is provided with a recess having an opening 112a. A light source unit 111, a reflector 113, and a lens 114 are arranged in the recess of the base 112. A frame-shaped baffle is arranged in the opening 112a of the base 112.

Further, as shown in FIGS. 2 to 4, the base 112 is provided with a plurality of heat radiation fins 112b. Each of the plurality of heat radiating fins 112b has a flat plate shape and is erected on the surface of the portion opposite to the recess of the appliance main body 110. By providing the heat radiating fins 112b, the heat generated by the light source unit 111 can be efficiently radiated.

[a reflector]
The reflector 113 shown in FIG. 4 is a reflecting member that reflects the light emitted from the light source unit 111. Specifically, the inner surface of the reflector 113 is a reflective surface that reflects the light from the light source unit 111, and the reflector 113 directs the light emitted from the light source unit 111 by the reflective surface in a desired direction. It is controlled to. In the present embodiment, the reflector 113 controls the light distribution so that the light emitted from the light source unit 111 is incident on the lens 114. As an example, the reflector 113 has a funnel-shaped cylindrical shape on the inner surface, and is configured such that the inner diameter gradually increases from the opening on the light incident side (light source side) toward the opening on the light emitting side. ..

The reflector 113 can be formed of, for example, a resin material or a metal material. Specifically, the reflector 113 may be a white resin molded product made of a resin material such as PBT (polybutylene terephthalate), or a metal film such as aluminum is formed on the inner surface of the resin molded product. It may be formed, or it may be a metal part formed of a metal material such as aluminum.

The reflector 113 configured in this way is attached to the base 112. Specifically, the reflector 113 is indirectly attached to the base 112 by being attached to a holder fixed to the base 112 in order to hold the light source unit 111 on the base 112.

[lens]
As shown in FIGS. 2 and 4, the lens 114 is arranged so as to cover the light source unit 111. Specifically, the lens 114 is attached to the base 112 so as to cover the opening of the reflector 113.

The lens 114 transmits the light emitted from the light source unit 111 and the light reflected by the reflector 113. Specifically, the lens 114 has a function of controlling the light distribution in a predetermined direction of the light emitted from the light source unit 111 and the light reflected by the reflector 113. In the present embodiment, the lens 114 has a Fresnel structure having a Fresnel lens function. The lens 114 also has a light diffusing structure. The light diffusion structure is, for example, a plurality of minute irregularities (dots, prisms) formed on the surface of the lens 114 on the light emitting side.

The lens 114 is made of a translucent material having translucency. Specifically, the lens 114 is made of a transparent resin material such as acrylic or polycarbonate, or a glass material.

[Frame body]
As shown in FIG. 1, the frame body portion 120 is a mounting member for mounting the lamp unit 100 to the opening 2a of the ceiling 2. Specifically, the frame body portion 120 is attached to the opening 2a of the ceiling 2 in order to hold the appliance main body 110 in the opening 2a of the ceiling 2.

As shown in FIGS. 3 and 4, the frame body portion 120 is configured as a frame body unit having a frame body 121, a support arm 122, and a mounting spring 123.

The frame body 121 has a cup-shaped substantially cylindrical shape having a first opening on the vertically lower side and a second opening on the vertically upper side. The frame body 121 is made of, for example, a metal material such as aluminum. In the present embodiment, the frame body 121 is made of die-cast aluminum. The material of the frame body 121 is not limited to the metal material, and may be a resin material.

A flange-shaped flange is formed in the first opening on the vertically lower side of the frame body 121. The flange of the frame body 121 is brought into contact with the ceiling surface 2b of the ceiling 2, and the inner side surface of the opening 2a of the ceiling 2 is pressed by three mounting springs 123 provided on the outer surface of the frame body 121. The unit 100 can be held in the opening 2a. The mounting spring 123 is an elastic member for mounting the lamp unit 100 to the opening 2a of the ceiling 2, and has a leaf spring structure. The mounting spring 123 is formed of, for example, an elongated metal plate.

The support arm 122 is a support plate made of a metal plate, and connects the frame body portion 120 and the instrument main body 110. In the present embodiment, the support arm 122 connects the frame main body 121 of the frame body portion 120 and the base 112 of the instrument main body 110.

The support arm 122 is provided with a slit 122a for rotating the instrument main body 110 to change the posture with respect to the ceiling surface 2b. Therefore, the slit 122a is formed with a constant width (slit width) along the rotation direction of the instrument main body 110.

The support arm 122 is sandwiched between the base 112 and the ring member 124 via the slit 122a. Specifically, the support arm 122 is sandwiched between a pair of ring members 124 having an outer diameter larger than the width of the slit 122a, the screw 125 is inserted into the through hole of each ring member 124, and the screw 125 is screwed into the base 112. Then, the support arm 122 is sandwiched between the base 112 and the ring member 124 by tightening the screws 125.

With this configuration, by rotating the base 112, the screw 125 screwed into the base 112 moves along the slit 122a. As a result, the instrument body 110 can be rotated along the shape of the slit 122a, so that the posture of the instrument body 110 with respect to the ceiling surface 2b can be changed.

The rotated instrument body 110 can be held at an arbitrary rotation angle by the holding force for holding the support arm 122 between the base 112 and the ring member 124. In this case, by adjusting the tightening torque of the screw 125, the holding force for holding the support arm 122 between the base 112 and the ring member 124 can be adjusted.

Further, the support arm 122 is configured to be rotatable with respect to the frame body portion 120 in a plane parallel to the ceiling surface 2b. Specifically, the end portion of the support arm 122 on the frame body portion 120 side is fixed to the frame body 121 so as to slide with the end surface of the opening on the ceiling 2 side of the frame body 121. As a result, the instrument main body 110 can be horizontally rotated in a plane parallel to the ceiling surface 2b.

The frame body portion 120 configured in this way surrounds a part of the instrument main body 110 with a gap G from the instrument main body 110. That is, there is a gap G along the circumferential direction between the frame body portion 120 and the instrument main body 110. In the present embodiment, the frame body portion 120 is arranged so that the frame body 121 surrounds the opening 112a of the base 112 of the instrument body 110, and the inner surface of the frame body 121 and the opening 112a of the base 112. There is a gap G between the side wall and the outer surface.

[Infrared communication module]
The infrared communication module 101 is provided in the lamp unit 100 and has a function of receiving an infrared signal. Specifically, the infrared communication module 101 converts the received infrared signal into a predetermined control signal (electric signal). Since the infrared communication module 101 in the present embodiment has only an infrared communication function, it is a small module.

As shown in FIGS. 4 and 5, the infrared communication module 101 is provided in the instrument main body 110. In the present embodiment, the infrared communication module 101 is attached to the side surface of the base 112 of the instrument main body 110. Specifically, the infrared communication module 101 is attached to the side surface of the heat radiation fin 112b of the base 112. Therefore, the infrared communication module 101 rotates in conjunction with the rotation of the instrument main body 110 (base 112).

Further, the infrared communication module 101 provided in the lamp unit 100 is provided in the fixture main body 110 so that the infrared signal can be received through the gap G between the frame body portion 120 and the fixture main body 110 (base 112). That is, the gap G is an opening for an infrared signal for passing an infrared signal.

As shown in FIG. 5, the infrared communication module 101 includes an infrared receiving unit 101a, a circuit board 101b, a case 101c, and a translucent cover 101d.

The infrared receiving unit 101a is a receiving unit that receives an infrared signal. Specifically, the infrared receiving unit 101a is an infrared receiving unit that receives infrared light which is an infrared signal. For example, the infrared receiver 101a receives an infrared signal transmitted from the infrared remote controller 3. The infrared receiving unit 101a is arranged at a position facing the through hole 101c1 provided in the case 101c.

An infrared receiver 101a is mounted on the circuit board 101b, and a plurality of circuit elements (not shown) are mounted on the circuit board 101b. The plurality of circuit elements mounted on the circuit board 101b constitute a processing circuit that converts an infrared signal received by the infrared receiving unit 101a into a predetermined control signal (electrical signal). The control signal generated by this processing circuit is transmitted to the control circuit 220 of the power supply unit 200 via the first electric wire 310.

The case 101c is a housing for accommodating the infrared receiver 101a and the circuit board 101b on which a plurality of circuit elements are mounted. The case 101c is made of resin, for example, but is not limited to this. Although the case 101c in the present embodiment is divided into two parts, it may be an integral part.

The case 101c is provided with a through hole 101c1 for passing an infrared signal. The through hole 101c1 of the infrared communication module 101 is arranged at a position facing the gap G between the frame body portion 120 and the instrument main body 110. As a result, the infrared receiving unit 101a is arranged at a position facing the gap G between the frame body portion 120 and the instrument main body 110 via the through hole 101c1 of the case 101c. As a result, the infrared signal transmitted from the infrared remote controller 3 reaches the infrared receiver 101a through the gap G between the frame body 120 and the instrument body 110.

The translucent cover 101d covers the through hole 101c1 provided in the case 101c. The translucent cover 101d is made of a material that transmits an infrared signal. The translucent cover 101d is a rectangular transparent plate, and is made of, for example, a transparent resin material or a glass material. By covering the through hole 101c1 with the translucent cover 101d, it is possible to prevent foreign matter such as dust from entering the case 101c through the through hole 101c1. As a result, it is possible to prevent dust and the like from adhering to the infrared receiving unit 101a and preventing the infrared signal from being correctly received.

[Rotating operation of the lamp unit]
Next, the rotational operation of the lamp unit 100 in the lighting fixture 1 according to the embodiment will be described with reference to FIG. FIG. 6 is a diagram for explaining the rotational operation of the lamp unit 100 in the lighting fixture 1 according to the embodiment.

6 (a1) and 6 (a2) show a state in which the instrument body 110 is not rotated and the optical axis JL of the instrument body 110 (light source unit 111) is parallel to the Z-axis direction. (B1) and (b2) show the state when the instrument main body 110 is rotated to the maximum.

In the lamp unit 100 of the present embodiment, the fixture main body 110 is supported by the frame body portion 120 so as to be rotatable (swinging). Specifically, the appliance main body 110 is rotatably supported by the frame body portion 120 so that the posture with respect to the ceiling surface 2b changes. By changing the posture of the fixture body 110 with respect to the ceiling surface 2b in this way, the light irradiation direction of the lamp unit 100 (light source unit 111) can be changed.

In the present embodiment, the instrument main body 110 is configured to be rotatable so as to swing in the rotation direction R1 with the axis parallel to the Y axis as the rotation axis JR1 (swing axis). At this time, as shown in FIGS. 6 (b1) and 6 (b2), the maximum movable angle α _{MAX at} which the instrument body 110 can rotate (swing) is, for example, 45 °, but it is not limited to this. Absent.

In the lamp unit 100, it is possible to hold the instrument main body 110 at a desired angle (swing angle) within the range of the maximum movable angle α _MAX , and by adjusting the swing angle of the instrument main body 110, light is emitted. The irradiation direction of the can be changed freely.

Further, the appliance main body 110 can not only change the posture with respect to the ceiling surface 2b, but also rotates in the direction of the rotation direction R2 with the direction perpendicular to the ceiling surface 2b (in the present embodiment, the Z-axis direction) as the rotation axis JR2. It is movable. That is, the appliance main body 110 can rotate horizontally in a plane parallel to the ceiling surface 2b. As a result, the appliance main body 110 can be rotated horizontally in a state of being tilted with respect to the ceiling surface 2b.

In the present embodiment, the instrument main body 110 is configured to be rotatable in the rotation direction R2 with the central axis of the frame body portion 120 as the rotation axis JR2. The maximum movable angle of the instrument body 110 in the rotation direction R2 is, for example, about 355 °, but is not limited to this.

In this way, the instrument body 110 is rotatable around the two axes of rotation axes JR1 and JR2, and the light emitted from the instrument body 110 (light source unit 111) is emitted by rotating the instrument body 110. The direction of travel can be changed.

Further, in the present embodiment, since the infrared communication module 101 is attached to the instrument body 110, by rotating the instrument body 110, the orientation of the infrared communication module 101 is also linked to the rotation of the instrument body 110. It will change. Thereby, the receivable range (detection area) of the infrared communication module 101 can be changed.

[Action effect]
Next, the action and effect of the lighting fixture 1 in the present embodiment will be described including the background to the present invention.

So far, as for lighting fixtures installed on the ceiling surface such as ceiling lights, those having a wireless communication function and an infrared communication function have been proposed. On the other hand, unlike ceiling lights, ceiling-embedded lighting fixtures such as downlights cannot perform both wireless communication and infrared communication because the power supply unit is located behind the ceiling.

In particular, the infrared receiving unit that receives the infrared signal cannot receive the infrared signal unless it is installed at a position where the infrared signal is not shielded by metal, a ceiling material, or the like. Further, if the user does not know the position of the infrared communication module (infrared receiver), the user does not know where to transmit the infrared signal.

In this respect, in the ceiling light, the power supply unit is located on the indoor side from the ceiling surface, and the power supply unit and the lamp unit (light source unit) are supported by the fixture main body and are arranged at the same position. For this reason, in the ceiling light, the user can install a communication module in which the wireless communication unit (wireless antenna, wireless processing circuit) and the infrared communication unit (infrared receiving unit, infrared processing circuit) are integrated in the power supply unit. By simply transmitting an infrared signal toward the ceiling light, not only wireless communication but also infrared communication can be performed.

However, in ceiling-embedded lighting fixtures such as downlights, the power supply unit is located behind the ceiling, so if a communication module that integrates a wireless communication unit and an infrared communication unit is mounted on the power supply unit, infrared rays will be emitted. Cannot receive the signal.

Therefore, in a ceiling-embedded lighting fixture, it is conceivable to mount a communication module in which a wireless communication unit and an infrared communication unit are integrated in a lamp unit instead of a power supply unit. However, if a communication module in which a wireless communication unit and an infrared communication unit are integrated is mounted on the lamp unit, the size of the lamp unit becomes large, the space for arranging the lamp unit becomes insufficient, or the ceiling 2 on which the lamp unit is installed is installed. The opening 2a of the is enlarged.

As described above, unlike ceiling lights, ceiling-embedded lighting fixtures such as downlights could not perform both wireless communication and infrared communication.

On the other hand, in the lighting fixture 1 of the present embodiment, as shown in FIG. 1, the wireless communication module 201 is mounted on the power supply unit 200 arranged behind the ceiling and embedded in the opening 2a of the ceiling 2. The infrared communication module 101 is mounted on the lighting unit 100. That is, the infrared communication module 101 and the wireless communication module 201 are separated, and the infrared communication module 101 is mounted on the lamp unit 100 that can be seen by the user.

By mounting the infrared communication module 101 on the lamp unit 100 embedded and arranged in the opening 2a of the ceiling 2 in this way, the user can easily perform infrared communication with the lighting equipment 1.

Specifically, when the user wants to control the illumination mode of the illumination light emitted from the lamp unit 100 (light source unit 111), the infrared signal is transmitted to the lamp unit 100 by operating the infrared remote control 3. The lighting mode of the lamp unit 100 (light source unit 111) can be controlled. For example, the lamp unit 100 (light source unit 111) can be turned on and off, the brightness of the illumination light can be changed, and the light color and color temperature can be changed.

Further, since the wireless communication module 201 is mounted on the power supply unit 200, the user can easily perform wireless communication with the lighting fixture 1. Specifically, when the user wants to make various settings of the lighting fixture 1, or when he / she wants to control the lighting mode of the lighting light emitted from the lighting fixture unit 100 (light source unit 111), he / she operates the wireless remote control 4 to generate a wireless signal. By transmitting, various settings of the lighting fixture 1 can be made, and the lighting mode of the lighting fixture unit 100 (light source unit 111) can be controlled.

Moreover, since the wireless communication module 201 is mounted not on the lamp unit 100 but on the power supply unit 200, it is possible to suppress an increase in the size of the lamp unit 100 and it is not necessary to increase the size of the opening 2a of the ceiling 2. It becomes.

As described above, according to the lighting fixture 1 in the present embodiment, both wireless communication and infrared communication can be performed even though the lighting fixture is a ceiling-embedded type lighting fixture.

Moreover, in the lighting fixture 1 of the present embodiment, the lighting fixture unit 100 is configured so that the posture of the light source unit 111 with respect to the ceiling surface 2b can be changed. Specifically, as shown in FIG. 6, the fixture body 110 is rotatable around two axes, and the light irradiation direction of the lamp unit 100 can be changed by rotating the fixture body 110. it can.

As a result, since the infrared communication module 101 is provided in the lamp unit 100, the reception range (detection area) of the infrared communication module 101 can be changed by rotating the fixture main body 110.

Further, in the lighting fixture 1 according to the present embodiment, since the infrared communication module 101 and the wireless communication module 201 are separately arranged, compared with the communication module in which the wireless communication unit and the infrared communication unit are integrated. , Each module can be miniaturized. As a result, the infrared communication module 101 and the wireless communication module 201 can be mounted without increasing the opening diameter of the opening 2a of the ceiling 2.

In particular, in the lighting fixture 1 of the present embodiment, the infrared communication module 101 is mounted on the lamp unit 100 visible to the user, but the infrared communication module 101 is a small module having only an infrared communication function. As a result, it is possible to prevent the design of the lamp unit 100 from being deteriorated by mounting the infrared communication module 101.

Further, the lighting fixture 1 in the present embodiment further includes a first electric wire 310 for transmitting a control signal corresponding to the infrared signal received by the infrared communication module 101 to the power supply unit 200.

Thereby, the power supply unit 200 processes the control signal corresponding to the infrared signal received by the infrared communication module 101, so that the illumination mode of the illumination light emitted from the lamp unit 100 (light source unit 111) can be controlled. That is, the infrared signal received by the infrared communication module 101 provided in the lighting unit 100 embedded in the opening 2a of the ceiling 2 is once transmitted as a control signal to the power supply unit 200 arranged behind the ceiling to supply power. After being processed by the circuit 210 and the control circuit 220, it is transmitted to the lamp unit 100 (light source unit 111) again to control the illumination mode of the illumination light. As a result, it is not necessary to separately mount a power supply circuit, a control circuit, or the like on the lamp unit 100, so that an increase in cost can be suppressed.

Further, as shown in FIG. 1, in the lighting fixture 1 of the present embodiment, the frame body portion 120 attached to the opening 2a of the ceiling 2 has a gap G between the fixture main body 110 and a part of the fixture main body 110. Surrounding. The infrared communication module 101 is provided in the instrument main body 110 so that an infrared signal can be received through the gap G. Specifically, as shown in FIG. 4, the infrared communication module 101 is provided on the base 112 of the instrument main body 110.

With this configuration, an infrared signal can be received from the gap G between the frame body 120 and the instrument body 110. As a result, it is not necessary to deform the shape of the appliance main body 110 (base 112) or the frame body portion 120 in order to secure a space for installing the infrared communication module 101. Therefore, since the existing instrument main body 110 or frame body 120 can be used while suppressing the deterioration of the design by providing the infrared communication module 101, both wireless communication and infrared communication can be performed at low cost. It is possible to realize a lighting fixture that can be performed.

(Modification 1 of the embodiment)
Next, the luminaire 1A according to the modified example of the first embodiment will be described with reference to FIG. 7. FIG. 7 is a cross-sectional view of the lamp unit 100A in the luminaire 1A according to the first modification of the embodiment.

In the lighting fixture 1 in the above embodiment, the infrared communication module 101 is provided on the side surface of the base 112 of the lamp unit 100, but in the lighting fixture 1A in this modification, the infrared communication module 101 is the lamp unit 100A. It is arranged near the light source unit 111 of.

Specifically, in this modification, the infrared communication module 101 is arranged between the reflector 113 and the base 112. Further, the reflector 113 is provided with a through hole 113a through which an infrared signal received by the infrared communication module 101 passes. Since the lens 114 is made of a transparent resin material or a glass material as in the above embodiment, the infrared signal passes through the lens 114. As a result, the infrared signal can reach the infrared receiving unit 101a (not shown) of the infrared communication module 101 through the lens 114 and the through hole 113a.

In this modification, the configuration is the same as that of the lighting fixture 1 in the above embodiment, including the power supply unit 200, except for the position of the infrared communication module 101.

As described above, according to the lighting fixture 1A in this modification, the infrared communication module 101 is arranged near the light source portion 111 of the lamp unit 100A.

Since the light source unit 111 is arranged at the center of the optical axis of the lamp unit 100, by arranging the infrared communication module 101 near the light source unit 111, the infrared communication module 101 is also arranged near the center of the optical axis of the lamp unit 100. To. This makes it easier for the infrared communication module 101 to receive infrared signals. That is, even if the user cannot recognize the position of the infrared communication module 101 (infrared receiving unit 101a), or even if the user does not try to recognize the position of the infrared communication module 101 (infrared receiving unit 101a), the infrared remote controller 3 It is possible to control the illumination mode of the illumination light of the lamp unit 100A only by transmitting an infrared signal to the lamp unit 100A.

Further, in the lighting fixture 1A in this modification, the infrared communication module 101 is arranged between the reflector 113 and the base 112.

As a result, the case 101c of the infrared communication module 101 can be hidden, so that it is possible to prevent the lamp unit 100A from being deteriorated in design by mounting the infrared communication module 101.

It is preferable that the through hole 113a of the reflector 113 is provided with a cap for closing the through hole 113a. This cap is a translucent cover and is made of a material that transmits infrared signals. In this case, as the cap material, a transparent resin material or a glass material may be used as in the lens 114. In this way, by closing the through hole 113a of the reflector 113 with a cap that transmits an infrared signal, the infrared communication module 101 receives the infrared signal through the through hole 113a, and foreign matter such as dust is received from the through hole 113a. It is possible to prevent the light from entering or leaking the light of the light source unit 111 from the through hole 113a.

(Modification 2 of the embodiment)
Next, the lighting fixture 1B according to the second modification of the embodiment will be described with reference to FIG. FIG. 8 is a cross-sectional view of the lamp unit 100B in the luminaire 1B according to the second modification of the embodiment.

In the luminaire 1 of the above embodiment, the infrared communication module 101 is provided on the side surface of the base 112 of the lamp unit 100, but in the luminaire 1B of the present modification, the luminaire 1A and the luminaire 1A of the modification 1 are used. Similarly, the infrared communication module 101 is arranged near the light source unit 111 of the lighting equipment unit 100B.

Further, in the lighting fixture 1A in the above modified example 1, the infrared communication module 101 is arranged between the reflector 113 and the base 112, but in the lighting fixture 1B in the present modified example, the infrared communication module 101 is It is arranged between the reflector 113 and the lens 114.

As described above, according to the luminaire 1B in the present modification, the infrared communication module 101 is arranged near the light source portion 111 of the lamp unit 100B, similarly to the luminaire 1A in the modification 1.

As a result, the illumination mode of the illumination light of the lamp unit 100B can be controlled only by transmitting the infrared signal toward the lamp unit 100B with the infrared remote controller 3.

Further, in the lighting fixture 1A in this modification, the infrared communication module 101 is arranged between the reflector 113 and the lens 114.

As a result, the infrared signal reaches the infrared communication module 101 only by passing through the lens 114. Therefore, the sensitivity of the infrared signal is improved as compared with the luminaire 1A in the first modification.

(Modification 3 of the embodiment)
Next, the luminaire 1C according to the third modification of the embodiment will be described with reference to FIG. FIG. 9 is a cross-sectional view of the lamp unit 100C in the luminaire 1C according to the third modification of the embodiment.

In the lighting fixture 1 of the above embodiment, the infrared communication module 101 is provided in the fixture main body 110 of the lamp unit 100, but in the lighting fixture 1B in this modification, the infrared communication module 101 is a frame of the lamp unit 100C. It is provided on the body portion 120. Specifically, the infrared communication module 101 is attached to the outer surface of the frame body 121.

With this configuration, the infrared receiving unit 101a of the infrared communication module 101 can be arranged at a position visible to the user while hiding the case 101c of the infrared communication module 101 behind the frame body 120. As a result, infrared communication with the luminaire 1 can be easily performed while suppressing deterioration of the design by providing the infrared communication module 101. That is, the user can easily control the illumination mode of the illumination light of the lamp unit 100 by transmitting the infrared signal to the infrared remote controller 3 toward the infrared receiver 101a.

Further, the frame main body 121 is provided with a through hole 121a through which an infrared signal received by the infrared communication module 101 passes. The through hole 121a is a small-diameter hole for receiving an infrared signal. In this modification, the through hole 121a is provided in the flange portion of the frame main body 121. That is, the through hole 121a is provided so as to be visible to the user.

With this configuration, the sensitivity of the infrared signal by the infrared communication module 101 can be improved, and the user can easily recognize the position of the infrared communication module 101 (infrared receiving unit 101a) by the position of the through hole 121a. .. As a result, the user can easily perform infrared communication with the luminaire 1 by pointing the infrared transmitter of the infrared remote controller 3 around the through hole 121a.

As in the modified example 2, the through hole 121a may be closed with a cap that transmits an infrared signal.

(Other variants)
The lighting fixture according to the present invention has been described above based on the embodiment, but the present invention is not limited to the above embodiment.

For example, in the above embodiment, one infrared communication module 101 is provided in the lamp unit 100, but the present invention is not limited to this. A plurality of infrared communication modules 101 may be provided in the lamp unit 100.

Further, in the above embodiment, an infrared cut filter for cutting the infrared component contained in the light emitted from the light source unit 111 may be arranged around the light source unit 111 or the like. For example, when the infrared communication module 101 is provided in the frame body 120, an infrared cut filter can be attached to the lens 114, or a member having an infrared cut filter can be attached to the front or rear of the lens 114. .. Further, instead of using an infrared cut filter, the lens 114 may include an infrared absorbing material for cutting an infrared component. By cutting the infrared component contained in the light emitted from the light source unit 111 in this way, it is possible to prevent unnecessary infrared rays from reaching the infrared communication module 101, so that false detection of the infrared communication module 101 can be suppressed. Can be done.

Further, in the above embodiment, the support arm 122 is used to configure the instrument main body 110 so as to be rotatable around two axes, but the present invention is not limited to this, and the instrument main body 110 is configured to have two axes by other configurations. It may be configured to be rotatable around.

Further, in the above embodiment, the light source unit 111 is configured to emit white light by the blue LED and the yellow phosphor, but the present invention is not limited to this. For example, a phosphor-containing resin containing a red phosphor and a green phosphor may be used, and the phosphor-containing resin and the blue LED may be combined to emit white light.

Further, in the above embodiment, a blue LED is used as the LED, but the present invention is not limited to this. For example, as the LED, one that emits light of a color other than blue or one that emits ultraviolet light may be used. In this case, the phosphor may be appropriately selected according to the wavelength of the light emitted by the LED.

Further, in the above embodiment, the light source unit 111 has a COB structure in which the LED chip is directly mounted on the mounting substrate, but the present invention is not limited to this. For example, an LED module having an SMD (Surface Mount Device) structure may be used instead of the LED module having a COB structure. An LED module having an SMD structure is a package-type LED element in which an LED chip (light emitting element) is mounted in a recess of a resin package (container) and a sealing member (fluorescent-containing resin) is sealed in the recess. This is a configuration in which one or more (SMD type LED elements) are mounted on a mounting board.

Further, in the above embodiment, the LED is exemplified as the light source of the light source unit 111, but the present invention is not limited to this. For example, as the light source of the light source unit 111, a semiconductor light emitting element such as a semiconductor laser, or a solid light emitting element other than an LED such as an organic EL (Electroluminescence) or an inorganic EL may be used, or a fluorescent lamp or a high brightness lamp. You may use an existing lamp such as.

In addition, it is realized by arbitrarily combining the components and functions in the above-described embodiment within the range obtained by applying various modifications to the above-described embodiment and not deviating from the gist of the present invention. Forms are also included in the present invention.

1, 1A, 1B, 1C Lighting equipment 2 Ceiling 2a Opening 2b Ceiling surface 100, 100A, 100B, 100C Lighting equipment unit 101 Infrared communication module 110 Equipment body 111 Light source unit 112 Base 113 Reflector 113a Through hole 114 Lens 120 Frame Part 121a Through hole 200 Power supply unit 201 Wireless communication module 310 First electric wire (electric wire)

Claims (9)

It is a ceiling-embedded lighting fixture.
A lamp unit having a light source unit that emits illumination light and is embedded in an opening of the ceiling.
It is arranged behind the ceiling and is equipped with a power supply unit that generates electric power to make the light source unit emit light.
The lamp unit is configured so that the posture of the light source unit with respect to the ceiling surface can be changed.
The lamp unit has an infrared communication module that receives an infrared signal for controlling the luminaire.
The power supply unit has a wireless communication module that receives a wireless signal for controlling the luminaire.
lighting equipment. Further, the infrared communication module includes an electric wire for transmitting a control signal corresponding to the infrared signal received by the infrared communication module to the power supply unit.
The lighting fixture according to claim 1. The lamp unit has a fixture main body having the light source portion and a frame body portion attached to the opening.
The frame body portion surrounds a part of the instrument body with a gap from the instrument body.
The infrared communication module is provided in the instrument body so that an infrared signal can be received through the gap.
The lighting fixture according to claim 1 or 2. The instrument body has a base on which the light source unit is arranged.
The infrared communication module is provided on the side surface of the base.
The lighting fixture according to claim 3. The infrared communication module is arranged near the light source unit.
The lighting fixture according to claim 1 or 2. The instrument main body has a base on which the light source portion is arranged and a reflector attached to the base and reflecting illumination light from the light source portion.
The infrared communication module is arranged between the reflector and the base.
The reflector is provided with a through hole through which an infrared signal received by the infrared communication module passes.
The lighting fixture according to claim 3 . The instrument body includes a base on which the light source unit is arranged, a reflector attached to the base and which reflects light emitted from the light source unit, and a lens that transmits light reflected by the reflector. Have and
The infrared communication module is arranged between the reflector and the lens.
The lighting fixture according to claim 3 . The lamp unit has a fixture main body having the light source portion and a frame body portion attached to the opening.
The frame body portion surrounds a part of the instrument body with a gap from the instrument body.
The infrared communication module is provided in the frame body portion and is provided.
The frame body is provided with a through hole through which an infrared signal received by the infrared communication module passes.
The lighting fixture according to claim 1 or 2. The infrared communication module receives an infrared signal for controlling the illumination mode of the illumination light as an infrared signal for controlling the luminaire.
The lighting fixture according to any one of claims 1 to 8.

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