JP5433291B2 - Task ambient lighting system - Google Patents

Description

  The present invention relates to a task ambient lighting system that includes an ambient lighting device and a task lighting device to save energy in room lighting.

  In this type of task ambient lighting system, general lighting to brighten the entire space such as offices is performed with ambient lighting equipment from the ceiling, etc., and the lighting required for visual work on the desk surface etc. is a short distance such as a desk lamp By using the task lighting fixtures from No. 1, the number of ambient lighting fixtures and the illuminance are reduced to save energy.

  In this type of task ambient lighting system, a control signal based on the lighting information is transmitted from the task lighting fixture to the ambient lighting fixture wirelessly or by wire, and the light output of the ambient lighting fixture is changed to the light output of the task lighting fixture by the control signal. A device that performs interlocking control so as to approach each other is known (for example, see Patent Document 1). As another task ambient lighting system, the ambient lighting fixture is controlled to a predetermined dimming level according to the lighting state of the task lighting fixture, and the task lighting and ambient lighting are linked to maintain the visual environment. Those that obtain an energy saving effect are known (see, for example, Patent Document 2).

  However, in the task ambient lighting system shown in Patent Document 1 and Patent Document 2 described above, since the inter-device communication for controlling the task lighting device and the ambient lighting device in conjunction with each other is a wireless or wired communication system, A separate transmitter and receiver for communication are required for the lighting fixture and the ambient lighting fixture, respectively. For this reason, the communication configuration is complicated, and in the case of wired communication, troublesome signal wiring is required for a task lighting fixture whose installation position such as a desk lamp on a desk is indefinite. There were times when radio interference was applied to the equipment.

JP-A-8-124680 Japanese Patent Laid-Open No. 9-204811

  The present invention solves the above-described problem, and an object thereof is to provide a task ambient lighting system capable of simplifying a communication configuration of a control signal for interlocking control between the ambient lighting device and the task lighting device. And

In order to achieve the above object, an invention according to claim 1 includes an ambient illuminator that illuminates a space, a task illuminator that is disposed within an irradiation range of the ambient illuminator and illuminates a work area, and the ambient illuminator. A task ambient lighting system having a main control unit that generates a control signal for controlling and a sub-control unit that generates a control signal for controlling the task lighting fixture, and detects the brightness of the space A brightness sensor, wherein the main control unit receives the detection signal of the brightness sensor and controls irradiation light of the ambient lighting fixture, and outputs an optical communication signal emitted from the ambient lighting fixture by the irradiation light control. The task illumination is received by a light receiving unit provided in the task lighting fixture, and the sub-control unit receives the task illumination by the optical communication signal received by the light receiving unit. It is intended to control the ingredients.

  According to a second aspect of the present invention, in the task ambient lighting system according to the first aspect, the peak wavelength in the light distribution of the irradiation light used in the optical communication method is 800 nm or less.

  According to the invention of claim 1, since a separate transmission facility for transmitting a control signal from the ambient lighting fixture to the task lighting fixture is not required, the communication configuration between both fixtures can be simplified. In addition, communication wiring is not required for the task lighting apparatus, and occurrence of radio wave interference can be avoided.

  According to the second aspect of the present invention, the irradiation range is narrowed to a range close to the range by the visible light irradiation by the irradiation light with a small infrared ray whose long wavelength side is limited, and the communication range can be easily grasped almost coincident with the irradiation range. Therefore, it becomes easy to take correspondence between the ambient lighting fixtures and the task lighting fixtures within the irradiation range to be controlled.

The block diagram of the task ambient lighting system which concerns on the 1st Embodiment of this invention. The block diagram of the ambient lighting fixture in the same system. The figure which shows the use condition of the task ambient lighting system which concerns on the 2nd Embodiment of this invention. The plane block diagram when the system is introduced on the office floor.

  Hereinafter, an ambient lighting system according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2. As shown in FIG. 1 and FIG. 2, the task ambient lighting system (hereinafter referred to as the present lighting system) of the present embodiment includes a plurality of ambient lighting fixtures 1 (1a, 1b, 1c) that illuminate a space such as an office, A plurality of task lighting fixtures 2 (2a, 2b, 2c) which are arranged within the irradiation range of the ambient lighting fixture 1 and illuminate the work area, and a control signal for controlling these lighting fixtures 1 and 2 are generated. A main control unit 3 and a brightness sensor 4 that detects the brightness of the space and transmits the brightness detection signal to the main control unit 3 are provided. In the present embodiment, when the main control unit 3 controls the task lighting device 2, it is performed by an optical communication method based on irradiation light control of the ambient lighting device 1.

  The ambient lighting fixture 1 includes a light source 11 including a discharge lamp, an incandescent lamp, an LED device, and the like, and a light source driving unit 12 that drives the light source 11, and is attached to a ceiling surface of an office space. The light source driving unit 12 drives the light source 11 based on a control signal from the main control unit 3, and emits irradiation light of an optical communication signal based on the control signal from the light source 11.

  The task lighting device 2 is installed on a desk or the like, and includes a desk lamp that illuminates around a user's work area. The task lighting fixture 2 also includes a light receiving unit 21 that receives an optical communication signal from the ambient lighting device 1, a sub-control unit 22 that controls lighting of the task lighting light source 23 based on the received signal, and a sub-control. And a light source 23 composed of a discharge lamp, an incandescent lamp, an LED device or the like that is controlled by the unit 22 to emit light.

  The main control unit 3 includes a microcomputer or the like and is provided on the ceiling surface or the ambient lighting fixture 1. The main control unit 3 generates a control signal for controlling the ambient lighting device 1 and the task lighting device 2 based on the brightness detection signal sent from the brightness sensor 4, and sends the control signal to the ambient lighting device 1.

  Here, the main control unit 3 includes a control signal for controlling the ambient lighting fixture 1 and the task lighting fixture 2, for example, an ambient control signal for controlling each output, and a task control signal composed of a pulse signal. Are generated and sent to the ambient lighting apparatus 1 as one control signal superimposed. For example, an ambient control signal is formed by a PWM signal (Pulse Width Modulation), and the PWM signal is subjected to pulse width modulation with a task control signal so that the total on-duty time within a predetermined time is constant, and the ambient lighting apparatus 1 The superimposition is performed so as to avoid the influence on the dimming control. Further, the ambient control signal and the task control signal may be transmitted through separate signal lines.

  The brightness sensor 4 is composed of a luminance sensor or an illuminance sensor using an optical sensor or the like, and is disposed on the ceiling surface, the ambient lighting fixture 1 or the like. Detect the brightness of the changing space. The arrangement of the brightness sensor 4 may be anywhere as long as the brightness of the space can be detected.

  In the present lighting system configured as described above, the main control unit 3 drives the light source driving unit 12 of the ambient lighting fixture 1 based on the control signal generated in response to the brightness detection signal from the brightness sensor 4 to emit the light source. The irradiation light from 11 is controlled. The light output of this irradiation light is controlled by an ambient control signal forming a PWM signal, and at the same time, blinking is controlled by a task control signal superimposed on the PWM signal.

  At this time, an optical communication signal blinked with a pulse signal in a frequency range that cannot be visually recognized by a person is transmitted by the irradiation light from the ambient lighting fixture 1. The light receiving unit 21 of each task lighting device 2 receives the optical communication signal and reproduces the task control signal, and the sub-control unit 22 controls the light source 23 based on the reproduced task control signal. In addition, when the several task lighting fixture 2 exists in the irradiation range of the one ambient lighting fixture 1, they can carry out interlocking control simultaneously.

  Here, the control of each light output of the ambient lighting apparatus 1 and the task lighting apparatus 2 by the main control unit 3 is, for example, when the space is bright, both the light outputs of the respective apparatuses 1 and 2 or the ambient lighting apparatus 1. In order to save energy, only the light output is controlled to be lowered to a predetermined brightness. In addition, when the space is dark, interlocking control is performed so as to improve the visual environment by increasing both the light output of each of the fixtures 1 and 2 or only the light output of the task lighting fixture 2 to a predetermined brightness. Note that the main control unit 3 may control the light output ratios of the appliances 1 and 2 to be a predetermined value according to the value of the brightness detection signal.

  According to the present embodiment, since the control signal from the main control unit 3 is transmitted to the task lighting device 2 by the irradiation light from the ambient lighting device 1, wireless or wired communication is used for inter-device communication for the interlock control. The communication configuration can be simplified without providing a separate transmission facility as in the system.

  Moreover, since it is wireless, the troublesome connection of the signal wire | line of the task lighting fixture 2 and the ambient lighting fixture 1 like the case where wired communication is used becomes unnecessary, the task lighting fixture 2 is installed on a desk and a power supply is connected. As a result, it can be easily used, and it is possible to avoid interference with surrounding electronic devices as in the case of using wireless communication.

  Next, a modification of the above embodiment will be described. In this modification, the wavelength of light used in the optical communication method is set to 800 nm or less in the above embodiment. Here, an LED device or the like is used as the light source 11 of the ambient lighting fixture 1. The visible light is, for example, 360-400 nm on the short wavelength side and 760-830 nm on the long wavelength side according to Japanese Industrial Standards optical terms (JISZ8120). Moreover, infrared rays are 780 nm-1000 micrometers according to the far-infrared term (JISZ8117), for example.

  The light receiving unit 21 of this modification has a light receiving element that receives visible light and is a visible light communication receiving unit that receives a visible light signal, and wavelength components other than visible light are included in the optical communication signal. Even if it is contained, the visible light component is mainly detected. As a result, the reception of unnecessary light such as infrared rays from a surrounding heat source or the like can be suppressed, so that it is difficult to receive noise and interference.

  According to the present modification, the irradiation light from the ambient lighting fixture 1 is limited to a visible range with a long wavelength side limited and visible with less infrared, so that the irradiation range is visible, and the irradiation range and the communication range are Since the communication range can be easily grasped substantially coincident with each other, it is easy to take correspondence between the ambient lighting device 1 and the task lighting device 2 that is within the irradiation range and is a control target.

  Therefore, it is difficult to set the communication range because it is difficult to see in the infrared communication method, and the communication radio wave covers a wide range in the wireless communication method. Therefore, frequent setting of a channel for specifying the task lighting device 2 in the communication range is required. Although rough prior setting is required, this modification does not have such a problem.

  Next, a task ambient lighting system according to the second embodiment of the present invention will be described with reference to FIG. The present embodiment further includes a timer 5 that generates time information and sends it to the main control unit 3, and a human sensor 6 for human detection, and each of the light sources 11 of the ambient lighting device 1 and the task lighting device 2, The light source 23 is an LED device that can change the color temperature (light color) of each irradiation light, and the other configuration is the same as that of the above-described embodiment. Here, the timer 5 is arranged in the vicinity of the main control unit 3, but may be built in the main control unit 3. In addition, the electric power to each lighting fixture etc. is supplied from the power outlet etc. installed in the ceiling 100, the floor surface 101, and the wall surface lower part.

  The ambient lighting fixture 1 and the brightness sensor 4 are installed on the top surface 100 of the office, and the light source 11 and the light source 23 are LED devices using red (R) LEDs, green (G) LEDs, blue (G) LEDs, and the like. Is provided. The wavelengths of the R, G, and B color LEDs are, for example, about 660 nm, about 520 nm, and about 450 nm, respectively.

  The task lighting device 2 is composed of an L-shaped support housing for supporting the light source 23, and is disposed on the task desk 102. The light receiving unit 21, the sub-control unit 22, and the light source 23 are disposed in a portion of the L-shaped support casing parallel to the desk surface, and the chair 103 is seated in a portion perpendicular to the desk surface. A human sensor 6 for detecting a person is arranged. The light source 23 includes R, G, and B color LEDs as described above.

  When the presence sensor 6 detects the presence / absence of a person in the task lighting device 2, the presence sensor 6 transmits the presence detection signal to the sub-control unit 22 via a transmission line (not shown) or the like. / The light source 23 is turned on / off in response to the absence. Thereby, the task lighting apparatus 2 is automatically turned off when a person is absent.

  The main control unit 3 adjusts the illuminance by controlling the emission intensities of the R, G, and B color LEDs of the light sources 11 and 23 according to the brightness detection signal from the brightness sensor 4 and from the timer 5. The color temperature of each of the light sources 11 and 23 is controlled by changing the color balance of the R, G and B color LEDs based on the time information. For example, the main control unit 3 changes the color temperature of the light source 11 according to the time zone such as morning, noon, and night by the time information from the timer 5, and sends the time information signal to the task lighting device 2 by visible light communication. And control the color temperature of the light source 23. The color temperature of each of the light sources 11 and 23 is basically set to a high color temperature in the morning time zone and a low color temperature in the night time zone. For example, 5000K (Kelvin) in the morning and noon, 3000K in the night, etc. It is good.

  According to the present embodiment, in addition to adjusting the illuminance of each of the ambient lighting device 1 and the task lighting device 2 according to the brightness of the space, the color temperature can be linked and controlled based on the time information of the timer 5. Energy saving can be achieved by detecting the presence / absence of the presence sensor 6. Here, the color temperature control is performed based on the time information of the timer 5, and the illuminance control is performed based on the brightness detection signal of the brightness sensor 4. However, the target illuminance is controlled based on the time information of the timer 5, and the brightness sensor 4 is controlled. It may be controlled to maintain the target illuminance by the brightness detection signal.

  FIG. 4 shows an example in which the office space is divided into a plurality of ambient lighting areas (here, A, B, C, and D), and the ambient lighting apparatus 1 and the task lighting apparatus 2 are linked and controlled for each lighting area. Show. Here, in an office where external light enters from a window or the like, a plurality of lighting areas, each of which includes two ambient lighting devices 1 and six task lighting devices 2, are formed, and are located near the center of the lighting areas. A brightness sensor 4 for detecting the brightness of each area is arranged on the ceiling surface or the like.

  In each of the illumination areas A, B, C, and D, the irradiation ranges thereof are set by the ambient lighting fixtures 1a, 1b, 1c, and 1d arranged in two each. Each task lighting device 2 (2a to 2d) is installed on a desk 102 arranged in parallel in two rows within the irradiation range of each irradiation area.

  The main control unit 3 is disposed on either the top surface (not shown) or a plurality of ambient lighting fixtures 1 (1a to 1d), and the main control unit 3, each ambient lighting fixture 1, and each brightness sensor. 4 are connected by transmission lines (not shown). The main control unit 3 controls the ambient lighting device 1 and the task lighting device 2 in each lighting area based on the brightness detection signal from each brightness sensor 4. The brightness detection range by each brightness sensor 4 substantially coincides with the irradiation range of each illumination area (A to D). The brightness sensor 4 estimates the brightness information of the area based on the image sensor that can acquire the brightness information of each illumination area as two-dimensional information or the brightness information of one point in each illumination area. Such a sensor may be used.

  In the above-described configuration, when the brightness of each illumination area changes mainly due to the incidence of natural light from the window, the main control unit 3 independently determines each illumination area based on the brightness detection signal from each brightness sensor 4. The light outputs of the ambient lighting device 1 and the task lighting device 2 are controlled in conjunction with each other.

  Here, in the lighting areas A and B and the lighting areas C and D, the task lighting fixtures 2 (in this case, corresponding to 2b and 2d) in the lighting area AB and the lighting area CD that overlap each other are two different. Since the irradiation light from the illumination area is received at the same time, it is necessary to prevent malfunction caused by duplicate reception.

  For this reason, when the modulation method of the control signal is frequency modulation (for example, FSK modulation), between the adjacent illumination areas (here, between A and B and between C and D), each ambient lighting apparatus 1 The modulation frequency of the control signal is set to be different from each other. Moreover, the task lighting fixture 2 in each irradiation area detects only a predetermined | prescribed modulation frequency from a received signal with the preset band pass filter. Thereby, each task lighting fixture 2 can be prevented from selecting a control signal transmitted from another irradiation area, and malfunction in the overlapping area range can be prevented.

  In this way, in a wide office space, brightness including natural light incident on the office and irradiation light in the office is detected for each lighting area, and the ambient lighting device 1 and the task lighting device 2 are detected for each lighting area. Since it is finely controlled, the energy saving effect is increased. Further, similarly to the above, the ambient lighting device 1 and the task lighting device 2 are both lighting devices such as LEDs capable of changing the color temperature, so that the color temperatures of both are synchronized with the timer 5 and controlled in conjunction with each other. be able to.

  In addition, this invention is not limited to the structure of the said various embodiment, A various deformation | transformation is possible suitably in the range which does not change the meaning of invention. For example, in each of the above-described embodiments, the one-way communication from the ambient lighting device 1 to the task lighting device 2 is performed. However, even if another communication method such as power line communication (PLC) is used in combination, the two-way communication may be used for interlock control. Good. Further, the optical communication unit 21 in the first embodiment may be a visible light communication receiving unit. Further, instead of the human sensor 6, a pressure sensor may be provided on a chair or the like, and human detection may be performed by human pressure.

1 Ambient lighting fixture 2 Task lighting fixture 3 Main control unit (control unit)
4 Brightness sensor

Claims (2)

An ambient lighting fixture that illuminates the space;
A task lighting fixture disposed within the irradiation range of the ambient lighting fixture and illuminating a work area;
A main control unit for generating a control signal for controlling the ambient lighting fixture;
A task ambient lighting system comprising: a sub-control unit that generates a control signal for controlling the task lighting fixture ,
It has a brightness sensor that detects the brightness of the space,
The main control unit receives the detection signal of the brightness sensor and controls the irradiation light of the ambient lighting fixture,
An optical communication signal irradiated from the ambient lighting fixture by the irradiation light control is received by an optical receiver provided in the task lighting fixture, and the sub-control unit receives the task by the optical communication signal received by the optical receiver. A task ambient lighting system characterized by controlling a lighting fixture .   The task ambient lighting system according to claim 1, wherein a peak wavelength in a light distribution of irradiation light used in the optical communication method is 800 nm or less.

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