JP5399883B2 - Lighting system - Google Patents

Description

  The present invention relates to a lighting system.

  Conventionally, an illumination system for controlling an illumination load by power line carrier communication has been provided (see, for example, Patent Document 1). In this lighting system, a controller that controls the entire system and a plurality of lighting fixtures that turn on, turn off, or dim a lighting load according to a control signal transmitted from the controller are connected via a power line. A signal is transmitted and received between the controller and each lighting fixture by superimposing a high-frequency current of a predetermined frequency on the controller. In each lighting fixture, the lighting load is turned on, turned off, or dimmed according to a control signal transmitted from the controller.

  Further, in this lighting system, a remote control receiving terminal is provided in a form corresponding to each lighting fixture, and the remote control receiving terminal receives individual lighting load information (for example, dimming level and level) transmitted as a wireless signal from the remote control setting device. When the color temperature or the like is received, the individual lighting load information is transmitted to the corresponding lighting fixture via the power line.

  However, since infrared rays generally used as a wireless signal are not visible, when a lighting fixture is placed close together, the wireless signal transmitted from the remote control setting device is not erroneously controlled by the adjacent remote control receiving terminal. There was a possibility of being received.

  In view of this, there has been proposed a lighting device that can irradiate visible light toward a lighting fixture so that the direction of infrared irradiation can be adjusted to the lighting fixture to be controlled (see, for example, Patent Document 2). The remote controller of this lighting device is provided with an infrared oscillator that transmits a wireless signal composed of infrared rays and a spotlight emitter that emits a spotlight of visible light, and the irradiation directions of these spotlights and infrared rays coincide with each other. In addition, both irradiation ranges are set to be substantially equal. Then, when remotely controlling the luminaire, the orientation of the remote controller is determined so that the spotlight is irradiated only to the luminaire to be controlled, and the wireless signal is transmitted in this state. As a result, the lighting load of the corresponding lighting fixture can be turned on, turned off, or dimmed.

Japanese Patent Laying-Open No. 2005-63803 (paragraph [0061] -paragraph [0062] and FIGS. 10 and 11) JP 2004-193971 A (paragraph [0011] -paragraph [0013] and FIGS. 1 and 3)

  Here, infrared rays generally used as wireless signals are reflected by a ceiling, a floor, a wall surface, a reflector of a lighting fixture, or the like, and therefore, the infrared irradiation range and the visible light irradiation range do not necessarily match. In addition, the light receiving range of a commonly used infrared remote control receiver module has a half-value angle of ± 30 ° or more, while the half-value angle of the infrared LED for transmission is ± 10 ° to 30 °. Therefore, in the lighting device shown in the cited document 2, for example, when infrared rays are transmitted from an oblique direction (a position where the distance between the remote controller and the lighting fixture is 3 m) with respect to the lighting fixture, the transmission range is a circle having a diameter of about 1 m. Therefore, there was a possibility that infrared rays would also enter the adjacent lighting fixture. On the contrary, if the infrared transmission range is narrow, there is a possibility that transmission data cannot be normally transmitted to the lighting device to be controlled due to a camera shake during data transmission.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an illumination system capable of reliably transmitting an infrared signal to a lighting fixture to be controlled.

The invention of claim 1 includes a controller comprising a first communication unit, the lighting load, the lighting circuit part for lighting the lighting load, a second communication unit for transmitting and receiving signals to and from said first communication unit a control unit for controlling the lighting state of the lighting load by controlling the output of the lighting circuit unit according to the control signal received by the second communication unit, the visible light receiving unit for receiving the visible light, and infrared signals 1 or a plurality of lighting fixtures equipped with a infrared receiving section for receiving, visible light emitting portion for irradiating visible light, and includes a predetermined set data, than the irradiation range of the visible light emitted from the visible light emitter and a remote control transmitter equipped with a infrared transmission unit that transmits an infrared signal emission range is set widely, the control unit, during the reception of the infrared signal, the irradiation the visible light receiving unit from the visible light emitter It has been of visible light When receiving a constant frequency components predetermined time, characterized by a validating the setting data included in the received infrared signal.

According to a second aspect of the invention, in the invention of claim 1, wherein the first communication unit and the second communication unit, using a predetermined carrier frequency, a signal by the power line carrier communication for superimposing a high-frequency current to the power line It is characterized by transmitting and receiving.

The invention of claim 3 is the invention of claim 1 or 2, wherein the visible light emitting unit is characterized in that it consists either of an LED or laser device for irradiating light having a predetermined single wavelength.

The invention of claim 4 is the invention of claim 3, wherein the light emitted from the LED or the laser device is irradiated, it characterized in that the light of blue wavelength.

The invention of claim 5 is the invention of claim 1, a plurality of the luminaires, the remote control transmitter comprises a setting unit for setting a dimming level or color temperature corresponding to the scene number and the scene number , wherein each of the luminaire, each provided with a storage unit for storing a dimming level or color temperature corresponding to the transmitted scene number and the scene number from the remote control transmitter, the control signal transmitted from the controller reads the corresponding dimming level or color temperature to a scene number included from the storage unit, the and controls the lighting load so as to read the dimming level or color temperature.

According to the invention of claim 1, since the irradiation range of the infrared signal is set wider than the irradiation range of the visible light emitted from the visible light emitting unit, the visible light emitted from the visible light emitting unit is, for example, camera shake. Therefore, even if the infrared light signal is removed from the visible light receiving unit, it is possible to suppress the infrared signal from being removed from the infrared receiving unit, and as a result, it is possible to suppress the infrared signal from being interrupted in the middle. On the other hand, it is sufficient that the visible light can be received for a predetermined time, so that there is an effect that an infrared signal can be received if the predetermined time has passed even if the visible light is removed from the middle. Furthermore, it is possible to distinguish the irradiation light or natural light of the illumination load from the visible light irradiated from the remote control transmitter, and there is an effect that the reliability of communication can be improved.

  According to the invention of claim 2, since signals are transmitted and received by power line carrier communication, there is no need to provide a dedicated signal line or the like, and there is an effect that construction is facilitated and cost increase can be suppressed.

According to the invention of claim 3 , as in the case of claim 1 , it is possible to distinguish the irradiation light or natural light of the illumination load from the visible light emitted from the remote control transmitter, and to improve the communication reliability. There is an effect that can be.

According to the invention of claim 4 , by increasing the wavelength difference with the infrared signal, it is possible to prevent the visible light from interfering with the infrared receiving unit and also prevent the infrared signal from interfering with the visible light receiving unit. There is an effect that can be done.

According to the invention of claim 5 , it is possible to control a plurality of lighting fixtures according to the scene by one control signal transmitted from the controller, and at the same time dimming or toning of each lighting fixture is possible, Further, in the case of power line carrier communication or wireless communication, there is an effect that the radio wave law is not restricted.

It is a block block diagram of the illumination system of this embodiment. It is a construction example same as above. It is the construction example of the lighting fixture used for the same as the above.

  Hereinafter, embodiments of a lighting system according to the present invention will be described with reference to the drawings. The illumination system according to the present invention is installed, for example, in an art museum, a museum, a store, or the like, and is used to illuminate exhibits or products. In addition, in the following description, the case where the communication system between a controller and each lighting fixture is a power line carrier communication is demonstrated.

FIG. 1 is a block diagram of a lighting system according to the present embodiment, and FIG. 2 is an example of the above construction. A plurality of (7 in FIG. 2) lighting fixtures 2 that are turned on, off, or dimmed, and individual addresses or group addresses for each lighting fixture 2 (used when setting a plurality of lighting fixtures as one group) A remote control transmitter 3 for setting a dimming level, a color temperature, etc. for each lighting scene (for example, daytime or nighttime), and the controller 1 and each lighting fixture 2 have a commercial AC power supply AC. Are electrically connected to each other via a power path 4 connected to the. In the following description, when it is necessary to distinguish the lighting fixture 2 is denoted as luminaires 2 ₁ to 2 ₇ distinguish.

  As shown in FIG. 1, the controller 1 uses a predetermined carrier frequency, a power line communication unit (first communication unit) 12 that transmits and receives signals by power line carrier communication in which a high-frequency current is superimposed on the power path 4, and a switch, for example And a control unit 11 that controls the power line communication unit 12 and the setting unit 13, for example, a construction surface such as a wall surface. It is used in the state attached to.

  As shown in FIG. 1, the luminaire 2 includes an illumination load 24 made of, for example, an incandescent lamp, a phase control circuit, and the like, and a lighting circuit unit that controls the dimming level of the illumination load 24 by changing the phase angle. 23 and a power line communication unit (second communication unit) 22 that transmits and receives signals between the power line communication unit 12 of the controller 1 and a lighting circuit unit 23 according to the control signal from the controller 1 received by the power line communication unit 22. A control unit 21 for controlling the output of the light source, an EEPROM or the like, and a storage unit 27 for storing individual illumination load information such as a dimming level and a color temperature, and a photodiode and a photo IC (photodiode, operational amplifier for amplification, etc.) A visible light receiving unit 25 configured to receive visible light emitted from a visible light emitting unit 32 of a remote control transmitter 3 to be described later, for example, An external line remote control light receiving module, and an infrared receiving unit 26 that receives an infrared signal transmitted from the infrared transmitting unit 33 of the remote control transmitter 3, for example, a wiring duct constructed on the ceiling surface as shown in FIG. 5 is attached via a fixture 28. The visible light receiver 25 and the infrared receiver 26 are provided side by side on the side wall of the fixture body 2A of the lighting fixture 2 as shown in FIG. In addition, the power line communication unit 22 is dedicated for reception, and at least in Japan, approval of the Radio Law is unnecessary, so that the degree of freedom in design can be increased.

  The visible light receiving unit 25 receives a predetermined frequency component of visible light emitted from a visible light emitting unit 32 of the remote control transmitter 3 to be described later, and a band pass filter or phase synchronization circuit having this frequency as a center frequency. (PLL) or the like. In addition, an optical filter that transmits light of a specific wavelength such as blue is added to the light receiving element, and visible light emitted from the visible light emitting unit 32 with disturbance light reflected from the floor surface by illumination light or natural light is reflected. To separate.

  As shown in FIG. 1, the remote control transmitter 3 is composed of, for example, an LED or a laser device, and includes a visible light emitting unit 32 that emits light of a predetermined single wavelength, an infrared remote control transmission LED, a driving transistor, and the like. And an infrared transmission unit 33 for transmitting an infrared signal including predetermined setting data (for example, individual address, group address, dimming level, color temperature, etc.) and a switch, LCD, LED, etc. And a setting unit 34 for setting a group address, a light control level, a color temperature, and the like, and a control unit 31 for controlling the visible light emitting unit 32, the infrared transmission unit 33, and the setting unit 34. Note that the light emitted from the visible light emitting unit 32 has a large wavelength difference from infrared rays so that interference with the infrared receiving unit 26 due to visible light and interference with the visible light receiving unit 25 due to infrared signals can be prevented. Light of a wavelength is desirable, and for example, it is obtained by turning on / off the light output of the LED (or laser device) constituting the visible light emitting unit 32 at a predetermined cycle. Here, the control units 11, 21, 31 are composed of, for example, a microcomputer.

  Here, the control signal transmitted from the controller 1 includes a scene number corresponding to each lighting scene (for example, daytime or nighttime), and the control unit 21 of the lighting fixture 2 stores it in the storage unit 27. The dimming level and color temperature corresponding to this scene number are read out from the individual lighting load information, and the lighting circuit unit 23 is controlled so that the read dimming level and color temperature are obtained, so that the lighting load 24 is lit. Is controlled.

  Next, a procedure for setting an individual address for each lighting fixture 2 will be described with reference to FIGS. First, an individual address to be set is displayed on the liquid crystal panel 35 by operating an operation key provided in the setting unit 34 of the remote control transmitter 3. Thereafter, the visible light irradiation button provided in the setting unit 34 is pressed to irradiate visible light having a predetermined frequency from the visible light emitting unit 32, and the optical axis of the visible light is aligned with the visible light receiving unit 25 of the luminaire 2 to be set. . When the infrared transmission button of the setting unit 34 is pressed with the visible light optical axis aligned with the visible light receiving unit 25, an infrared signal including an individual address is transmitted from the infrared transmission unit 33 to the infrared reception unit 26. Is done. Here, since the irradiation range of the infrared signal (region b in FIG. 2) is set wider than the irradiation range of visible light (region a in FIG. 2), the optical axis of the visible light is set to the visible light receiving unit. By adjusting to 25, the above infrared signal can be reliably received by the infrared receiver 26.

  On the other hand, in the lighting fixture 2, when the visible light receiving unit 25 receives the visible light emitted from the visible light emitting unit 32 while the infrared receiving unit 26 receives the infrared signal transmitted from the infrared transmitting unit 33, The control unit 21 turns on the flag, and determines that the individual address included in the infrared signal received by the infrared receiving unit 26 is valid while the flag is on, and causes the storage unit 27 to store the individual address. Therefore, the individual address received with the flag being OFF is not stored in the storage unit 27 but discarded. Note that the above flag remains ON while the visible light receiving unit 25 continues to receive visible light, and even if the visible light receiving unit 25 does not receive visible light for a certain time (for example, The ON state is maintained for a time longer than the time required for setting), and is turned OFF after a predetermined time has elapsed.

  By sequentially performing the above procedure for each lighting fixture 2, an individual address is set for each lighting fixture 2. Since the same procedure is used when setting the group address and the light control level (or color temperature), the description is omitted here.

  Here, Table 1 shows the dimming level set for each lighting fixture 2, and in this embodiment, the dimming level can be set for each lighting scene. Each lighting scene is assigned with a scene number, and each lighting fixture 2 stores the scene number and the dimming level in the storage unit 27 in association with each other.

According to Table 1, for example, when the scene number included in the control signal transmitted from the controller 1 is “3 (lunch break)”, the lighting fixtures 2 ₁ to 2 ₄ belonging to the group 1 each have a dimming level. 60%, 50%, 50%, and 30% are set, and the dimming levels of all the lighting fixtures 2 ₅ to 2 ₈ belonging to the group 2 are set to 30%. That is, according to the present embodiment, it is possible to control the plurality of lighting fixtures 2 with one control signal (scene number corresponding to the lighting scene).

  Next, the operation of the present illumination system will be described. In the following description, it is assumed that the time at which each lighting scene is started is preset in the controller 1. When the time is measured by a timer or a real-time clock IC provided in the controller 11 of the controller 1 and the current time is the time to start any lighting scene, the controller 1 sends a control signal including a scene number from the power line communication unit 12. The light fixture 2 is sent to the power path 4 and the power line communication unit 22 receives the control signal. Then, the dimming level corresponding to the scene number included in the received control signal is read from the storage unit 27, and the lighting circuit unit 23 is controlled so as to be the read dimming level to control the lighting state of the lighting load 24. It is. Note that the power line communication unit 22 included in the lighting fixture 2 is dedicated for reception, and a reply signal (ACK signal) is not transmitted from the lighting fixture 2 side. In this embodiment, in order to ensure the reliability of communication, the following The control signal is repeatedly transmitted until the lighting scene starts.

  Thus, according to the present embodiment, since the irradiation range of the infrared signal is set wider than the irradiation range of the visible light emitted from the visible light emitting unit 32, the visible light emitted from the visible light emitting unit 32 is set. However, it is possible to prevent the infrared signal from being disconnected from the infrared receiving unit 26 even if the visible light receiving unit 25 is detached due to camera shake, and as a result, the infrared signal can be prevented from being interrupted in the middle. On the other hand, as long as visible light can be received for a predetermined time, an infrared signal can be received if the predetermined time has elapsed even if the visible light is removed from the visible light receiving unit 25 on the way.

  In addition, when signals are transmitted / received by power line carrier communication as in the present embodiment, it is not necessary to provide a dedicated signal line or the like, so that construction can be facilitated and cost increase can be suppressed. Further, the visible light emitted from the visible light emitting unit 32 is set to a frequency different from that of the illumination load 24 and natural light, so that the visible light emitted from the remote control transmitter 3 It can be distinguished from natural light, and the reliability of communication can be improved. In particular, by making the light emitted from the visible light emitting unit 32 light of a blue wavelength, the wavelength difference from the infrared signal is increased, As a result, it is possible to prevent the visible light from interfering with the infrared receiving unit 26, and it is possible to prevent the infrared signal from interfering with the visible light receiving unit 25.

  In addition, a plurality of lighting fixtures 2 can be controlled in accordance with a scene by one control signal (scene number corresponding to each lighting scene in the present embodiment) transmitted from the controller 1, and each lighting fixture 2 is simultaneously controlled. There is an advantage that light adjustment or color adjustment is possible. In addition, in the case of power line carrier communication or wireless communication as in this embodiment, there is an advantage that the terminal is a reception-only terminal and is not restricted by the Radio Law.

  In the present embodiment, the case where the number of the lighting fixtures 2 is seven has been described as an example. However, the number of the lighting fixtures 2 is not limited to this embodiment, and at least one lighting fixture may be used. Further, the illumination load 24 is not limited to the incandescent lamp, and may be a fluorescent lamp or an LED. In the case of a fluorescent lamp, the lighting circuit unit 33 is configured with a copper-iron ballast and a phase control circuit, and the dimming control is performed by changing the phase angle, and the rectifier circuit that rectifies the commercial AC power supply AC and the input current distortion The lighting circuit unit 33 may be configured with an inverter circuit or the like for the boosting chopper circuit and high-frequency power to be suppressed, and the high-frequency power supplied to the fluorescent lamp may be controlled by changing the operating frequency of the inverter circuit. In the case of an LED, the lighting circuit unit 33 is configured by a PWM circuit or the like that converts a DC voltage into a pulse voltage, and the dimming level is controlled by changing the duty ratio of a pulse applied to the LED. The color of each RGB LED may be dimmed to control the color of the RGB composite light.

  Furthermore, in the present embodiment, the case where the communication method between the controller 1 and the lighting fixture 2 is the power line carrier communication has been described. However, the communication method is not limited to the present embodiment, and for example, a dedicated communication line is used. It may be used or wireless communication using radio waves. In the present embodiment, only the dimming level (or color temperature) is stored in the storage unit 27. However, for example, a fade rate (for example, a dimming level that changes in one minute) is stored together with the dimming level. You may make it do. Furthermore, although this embodiment demonstrated the case where the light control level was set for every lighting fixture 2, you may set a light control level for every group 1 and 2 shown in Table 1, for example.

DESCRIPTION OF SYMBOLS 1 Controller 2 Lighting fixture 3 Remote control transmitter 12 Power line communication part (1st communication part)
21 Control unit 22 Power line communication unit (second communication unit)
23 lighting circuit section 24 lighting load 25 visible light receiving section 26 infrared receiving section 32 visible light emitting section 33 infrared transmitting section

Claims (5)

A controller having a first communication unit;
Lighting load, the lighting load lighting circuit unit to turn on the second communication unit for transmitting and receiving signals to and from said first communication unit, of the lighting circuit unit according to the control signal received by the second communication unit control unit for controlling the lighting state of the lighting load by controlling the output, one to a plurality of luminaires equipped with a infrared receiving section for receiving the visible light receiving unit, and an infrared signal receiving visible light,
Visible light emitting portion for irradiating visible light, and includes a predetermined set data, the infrared ray transmitting unit that transmits an infrared signal emission range is set wider than the irradiation range of the visible light emitted from the visible light emitter Equipped with a remote control transmitter,
Wherein, during the reception of the infrared signal, the the visible light receiving unit is a predetermined time receiving a predetermined frequency component of the irradiated visible light from the visible light emitting portion, the setting data included in the received infrared signal A lighting system characterized by making effective. The first communication unit and the second communication unit, the lighting system of claim 1, wherein the transmit and receive signals using a predetermined carrier frequency, the power line communications for superimposing a high-frequency current to the power line . The illumination system according to claim 1, wherein the visible light emitting unit includes any one of an LED or a laser device that emits light having a predetermined single wavelength . 4. The illumination system according to claim 3, wherein the light emitted from the LED or the laser device is blue wavelength light . A plurality of the lighting fixtures,
The remote control transmitter includes a setting unit for setting a scene number and a dimming level or color temperature corresponding to the scene number,
Each of the lighting fixtures includes a storage unit that stores a scene number transmitted from the remote control transmitter and a dimming level or a color temperature corresponding to the scene number, and the control signal transmitted from the controller is included in the control signal. lighting system according to claim 1, wherein the corresponding dimming level or color temperature scene number read from the storage unit, and controls the lighting load so as to read the dimming level or color temperature included .

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