JP3846001B2 - Lighting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an illuminating device, and more particularly to an illuminating device that detects an ambient condition and controls an illumination load.
[0002]
[Prior art]
  Recently, lighting devices that have a lighting function that is gentle on the eyes and that provide lighting that does not cause discomfort due to lighting are on the market. As such an illuminating device, there exists an illuminating device described in Unexamined-Japanese-Patent No. 5-114489 or Unexamined-Japanese-Patent No. 9-223585, for example.
[0003]
  The illumination device described in Japanese Patent Application Laid-Open No. 5-114489 has a human body detection unit that detects the presence or absence and movement of a person in a detection region and an illuminance detection unit that detects ambient illuminance, and is detected by the illuminance detection unit. When the human body is detected by the human body detector when the ambient illuminance is lower than the preset illuminance, the lighting load is faded in to the lighting state with a predetermined inclination as shown in FIG. In addition, the high-intensity lighting state is maintained for a preset time.
[0004]
  In addition, the illumination device described in JP-A-9-223585 includes a human body detection unit that detects the presence or absence and movement of a person in the detection region, a power control unit that controls power supplied to the illumination load, Timer that counts lighting holding time to hold lighting state of lighting load after human body detection, forced lighting mode to forcibly turn on lighting load regardless of presence or absence of human body detection, lighting above when human body is detected by human body detection unit It includes at least a change-over switch for switching to the normal mode for lighting the illumination load for the holding time or the sleep mode. Here, when the normal mode is switched to the sleep mode, the lighting level of the illumination load is lowered from the rated level to a considerably low dimming level (for example, about 5 to 40% when the rated level is set to 100%) to detect the human body. When a human body is detected by the unit, the light is slowly faded in from the extinguished state to the dimming level (see FIG. 17).
[0005]
  By the way, in the illuminating device provided with the above-mentioned human body detection part, generally the control which detects a human body, lights up an illumination load, and turns off automatically after a predetermined time is performed. For example, if the human body detection unit is of a pyroelectric type, human movement may not be performed due to a small amount of human movement, and the lighting load is turned off after a predetermined time despite the presence of a human in the detection area. May end up. At this time, in order to turn on the illumination load again, it is necessary to move so that a person existing in the detection region is detected by the human body detection unit in the dark. In order to avoid such problems, the output is gradually reduced (fade out) when the lighting load is turned off.To do)What should I do? Further, in order to notify the user that the lighting load will soon be turned off, there is also a lighting device having a so-called turn-off notification function in which the fade-out is stopped for a few seconds in the middle of the fade-out and the light is turned on at a constant output.
[0006]
  However, in the conventional lighting device, when the human body is detected by the human body detection unit in a state in which the lighting load is turned off (during fading out), the lighting load is faded in at a constant inclination as in the conventional example described in the above publication. Control was performed. That is, the gradient of the fade-in when the lighting load is turned on in the same mode is constant (see FIGS. 16 and 17).
[0007]
[Problems to be solved by the invention]
  However, when the lighting load is automatically turned off as described above, the fact that the person has confirmed the lighting state by the fade-out of the lighting load or the turning-off notification function means that at least the person in the detection area of the human body detection unit Indicates that it still exists. Therefore, in this situation, when the output of the illumination load is increased again (fading in), the lighting is performed by fading in at a faster speed (tilting) than when fading in at the same speed (tilting) as usual. It is desirable to light up the load early to provide the user with the original brightness.
[0008]
  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a comfortable light by changing the slope of a fade-in when lighting a lighting load according to the situation. It is in providing the illuminating device which can be performed.
[0009]
[Means for Solving the Problems]
  Claim 1In order to achieve the above object, the invention provides a lighting load,Human body that detects human presence / absence and movement within detection range and outputs human detection signalDetection means;Ambient illuminance detection means for outputting an illuminance level signal according to the ambient illuminance;the aboveHuman body detection means and ambient illuminationA control means for varying the amount of power supplied to the lighting load from an external power source according to a detection result by the detection means, and for turning on, turning off, and dimming the lighting load, the control means,Fading out that gradually lowers the output level of the lighting loadIf an external trigger signal is inputWhen the lighting load is faded in according to the detection result by the human body detection means and the ambient illuminance detection meansThe lighting load fades in at a slope larger than a predetermined slope and lights up.Do.
[0010]
  In order to achieve the above object, the invention according to claim 2 corresponds to the illumination load, the human body detecting means for detecting the presence / absence or movement of a person in the detection range and outputting a human body detection signal, and the ambient illuminance. Ambient illuminance detection means for outputting an illuminance level signal, and the amount of power supplied from the external power source to the illumination load is varied according to the detection results of the human body detection means and the ambient illuminance detection means, and the lighting load is turned on / off. And a control means for performing dimming, the control means counts a predetermined lighting holding time from the time when the human body detection signal is input, and lights the illumination load at a predetermined output level during the counting. If the external trigger signal is input when the lighting holding time is being counted, the lighting load is adjusted according to the detection results of the human body detection means and the ambient illuminance detection means. With greater inclination than the predetermined gradient when Doyne, characterized in that light the fade the lighting load.
[0011]
  The invention of claim 3 is the invention of claim 1, wherein the human body detection signal is used as the trigger signal.
  According to a fourth aspect of the present invention, there is provided a lighting device comprising at least the lighting load, a control unit, and a receiving unit for receiving a remote control signal, and at least the detection unit and a detection result by the detection unit. And a transmitter for transmitting the remote control signal, wherein the remote control signal is used as the trigger signal.
  The invention of claim 5 is characterized in that, in the invention of claim 2, the illuminance level signal that is below a predetermined level is used as the trigger signal.
  According to a sixth aspect of the present invention, in any one of the first to fifth aspects of the present invention, the control means changes the slope of fade-in when the lighting load is turned on according to a time zone.
[0012]
  A seventh aspect of the present invention provides the method according to any one of the first to fifth aspects, wherein the control means determines a slope when fading in when the trigger signal is input, when the trigger signal is input. The lower the output level of the illumination load is, the larger it is.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, before describing embodiments of the present invention, a basic example in which some of the configuration requirements are common to the present invention will be described.
  (Basic example1)
  FIG. 1 illustrates the present invention.Basic example1 is a block diagram showing 1. FIG. BookBasic exampleThe lighting apparatus includes an illumination load 1 such as a light bulb and a discharge lamp, an illumination load control unit 2 that varies the amount of power supplied from the commercial AC power supply AC to the illumination load 1, and the amount of power supplied to the illumination load 1. A control unit 3 for turning on / off and dimming the lighting load 1 by outputting a load control signal for adjusting the lighting to the lighting load control unit 2, and human body detection for detecting the presence / absence and movement of a person in the detection region The lighting load control unit 2 and the control unit 3 constitute a control means, and the human body detection unit 4 constitutes a detection means. In addition,FigureAlthough not shown, an operation unit may be provided for giving instructions to the control unit 3 such as turning on, turning off, and dimming.
[0014]
  For example, if the lighting load 1 is a light bulb, the lighting load control unit 2 varies the amount of power supplied to the lighting load 1 by phase-controlling the power supply voltage of the commercial AC power supply AC using a triac. If the load 1 is a discharge lamp, it is composed of an inverter circuit, and the amount of power supplied to the lighting load 1 can be varied by adjusting its oscillation frequency.
[0015]
  The control unit 3 includes a microcomputer as a main component, and generates a load control signal for turning on / off and dimming the lighting load 1 in accordance with a signal input from the operation unit 4. The load control signal is, for example, a signal that determines the on period of the triac or a signal that determines the oscillation frequency of the inverter circuit.
  The human body detection unit 4 includes a pyroelectric infrared sensor 4a that detects a change in infrared according to the movement of the human body, an amplification unit 4b that amplifies the amount of change in infrared detected by the infrared sensor 4a, and an amplification by the amplification unit 4b. A comparison unit 4c that compares the detected change amount with a reference level and outputs a human body detection signal when the change amount exceeds the reference level, and indicates a human presence or absence (movement) in the detection region A detection signal is output to the control unit 3.
[0016]
  Thus, the control unit 3 receives a human body detection signal from the human body detection unit 4 or a signal from an operation unit (not shown), determines these signals, and determines the lighting load 1 according to the set operation mode. A load control signal for turning on, turning off, and dimming is generated, and the load control signal is output to the illumination load control unit 2 to perform control according to the operation mode.
  Next bookBasic exampleWill be described in detail with reference to FIGS. BookBasic exampleThe normal operation is basically the same as the operation described in the conventional example. When a human body detection signal is input from the human body detection unit 4, the control unit 3 changes the output of the illumination load 1 from 0% to 100% (rated A load control signal that gradually increases (fades in) to the output or maximum output) is generated, and the load control signal is output to the lighting load control unit 2 to turn on the lighting load 1. The fade-in speed at this time is, for example, a speed at which the output of the lighting load 1 is continuously increased from 0% to 100% in 0.8 seconds. In the following description, the fade-in speed (slope) defined above is expressed as V (0.8)._0-100Is written. Similarly, the speed (gradient) when the output of lighting load 1 is continuously reduced (faded out) from 100% to 0% in 0.8 seconds is V (0.8)._100-0Is written.
[0017]
  Further, the timer 3 a included in the control unit 3 counts the time τ that continues lighting the lighting load 1 from the time when the human body detection signal is input from the human body detection unit 4 (hereinafter referred to as “lighting holding time”) τ. To start. The control unit 3 lights the lighting load 1 at a predetermined level (for example, 100% full lighting) while the timer 3a counts the lighting holding time τ, and the timer 3a counts the lighting holding time τ. When completed, the lighting load 1 is turned off by gradually decreasing the output (fading out). The fade-out speed (gradient) at this time is a speed at which the output of the illumination load 1 is continuously reduced from 100% to 0% in 0.8 seconds, and the absolute value is the same as the fade-in speed. However, in order to inform the user that the lighting load 1 will be extinguished soon, the control unit 3 stops the fade-out for a few seconds in the middle of the fade-out and keeps a constant output (for example, 50%, but is not limited to this). ) (Lights off notification function). Note that the fade-out may be started so that the lighting load 1 is turned off when the timer 3a finishes counting the lighting holding time τ.
[0018]
  Here, when the human body detection signal is input from the human body detection unit 4 while the fade-out is stopped halfway and the lighting load 1 is turned on with a constant output by the turn-off notification function, the control unit 3 The counting operation of the lighting holding time τ of 3a is reset and the counting of the lighting holding time τ is started again from the beginning, and the fade-in is performed so that the lighting load 1 is returned to the initial lighting state (lighting state with 100% output). Do.
[0019]
  At this time, as shown in FIG. 3, the control unit 3 fades the fade-in speed (inclination) for returning the illumination load 1 to the initial lighting state from the off state (0%) to the full lighting state (100%). For example, the speed at which the output of the lighting load 1 is continuously increased from 0% to 100% in 0.2 seconds (= V (0.2)_0-100) Fade in. On the other hand, in the conventional example, as shown in FIG. 4, the fade-in for returning the illumination load 1 to the initial lighting state is equal to the speed at which fade-in is first performed from the extinguished state to full lighting (= V (0.8))._0-100)Basic exampleWhen the human body detection signal is input when the output of the lighting load 1 is a constant value (50%) as described above, the user notices the light-off notification state by performing a faster fade-in than the normal fade-in. When the lighting load 1 is to be fully turned on again, the lighting load 1 can be turned on in a short time earlier than the normal time, and a more comfortable light can be provided to the user. In addition, since the user is under illumination by the lighting load 1 until the time of fading out, there is a possibility that the user may feel uncomfortable even if performing fading in faster than usual from the middle of fading out as described above. Absent.
[0020]
  (Basic example2)
  FIG. 5 illustrates the present invention.Basic example2 is a block diagram showing 2. FIG. BookBasic exampleThen, the lighting apparatus is comprised by the lighting fixture 10 and the transmitter 20. FIG. The lighting fixture 10Basic example1 includes an illumination load 1, an illumination load control unit 2, a control unit 3, and a reception unit 11, and the transmitter 20 includes a human body detection unit 4, an internal power supply unit 21 including a storage battery, a transmitter control unit 22, and a transmission unit 23. The transmitter controller 22 also includes a timer 22a. In addition,Basic exampleThe parts having the same functions as those in FIG.
[0021]
  Thus, when a human body detection signal is input from the human body detection unit 4 to the transmitter control unit 22, the transmitter 20 controls the transmission unit 23 to transmit a wireless signal with a code corresponding to the load control signal. Here, the transmission unit 23 includes a light emitting diode (LED) 23a that emits infrared light, and transmits the wireless signal using infrared light emitted from the light emitting diode 23a.
[0022]
  On the other hand, the wireless signal from the transmitter 20 is received by the receiving unit 11 of the lighting fixture 10 and sent to the control unit 3. Then, a load control signal is generated based on the wireless signal received by the control unit 3, and the generated load control signal is output to the illumination load control unit 2 to control the lighting load 1 to be turned on / off, dimming, etc. Do it. For specific operations,Basic exampleThe description is omitted because it is common to 1.
[0023]
  BookBasic exampleThen, by separating the illuminating device into the illumination load 10 including the illumination load 1, the illumination load control unit 2 and the control unit 3, and the transmitter 20 including the human body detection unit 4,Basic exampleThere is an advantage that the same operational effects as 1 can be achieved and at the same time, the degree of freedom of the installation location of the human body detection unit 4 can be expanded and the usability is improved.
  (Basic example3)
  BookBasic exampleThe configuration ofBasic example1 and the illustration and description thereof are omitted.Basic exampleIn 1 and 2, when the human body detection signal is input when the turn-off notification function is activated during the fade-out and the output of the lighting load 1 is maintained at a constant value (50%), the control unit 3 performs the normal fade. Fade-in faster than Inn, but bookBasic exampleThenBasic exampleSimilar to 1 or 2, the control unit 3 normally starts from that point not only when the output of the lighting load 1 is maintained at a constant value (50%) but also when a human body detection signal is input during the fade-out. The fade-in is faster than the previous fade-in.
[0024]
  Thus, as shown in FIG. 6, when the human body detection signal is input during the fade-out until reaching the constant value (50%) at which the turn-off notification function works, or the turn-off notification function ends as shown in FIG. Then, when a human body detection signal is input during the fade-out from the fixed value (50%) to the extinguishing (0%), the control unit 3 causes the fade-in speed to return the lighting load 1 to the initial lighting state. (Inclination) is faster than the speed at which fade-in is first performed from the extinguished state (0%) to full lighting (100%). For example, the output of the lighting load 1 is continuously from 0% to 100% in 0.2 seconds. Increase speed (= V (0.2)_0-100) Fade in.
[0025]
  BookBasic exampleIf the human body detection signal is input in the middle of the fade-out as in the above, if the control unit 3 performs a fade-in faster than a normal fade-in from that point,Basic exampleMore comfort than 1 or 2 is obtained.
  (Embodiment1)
  FIG. 8 shows an embodiment of the present invention.1Is a block diagram showingBasic example1 is provided with an illuminance detection unit 5, but the configuration other than the illuminance detection unit 5 isBasic example1 are the same as those in FIG.
[0026]
  The illuminance detection unit 5 includes an illuminance sensor 5a made of a photoelectric conversion element such as CdS and an amplification unit 5b that amplifies the output of the illuminance sensor 5a, and outputs an illuminance level signal corresponding to the ambient illuminance to the control unit 3. To do.
  by the way,Basic example1 to 3, when the human body detection signal is input when the output of the lighting load 1 is equal to or higher than a predetermined value, the control unit 3 performs a fade-in faster than a normal fade-in.Basic exampleThen, when the output of the illumination load 1 is 0% (when the light is off), the illuminance level signal from the illuminance detection unit 5 sets the threshold value.BelowIn this case, the control unit 3 performs the fade-in faster than the normal fade-in, and the feature of this embodiment is that such control is performed.
[0027]
  Next, the operation of this embodiment will be described in detail with reference to FIG. First, in a normal operation, when a human body detection signal is input from the human body detection unit 4, the control unit 3 causes the timer 4 a to start counting the lighting holding time τ. If the surroundings are dark at this time, that is, from the illuminance detection unit 5. The input illuminance level signalunderIf it is rotating, lighting is necessary, so the lighting load 1 is set to normal speed (= V (0.8)_0-100) Fade in. Then, when the lighting holding time τ is counted by the timer 4a, fade-out is started at a timing such that the lighting load 1 is turned off.
[0028]
  On the other hand, if the surroundings are bright when the human body detection signal is input, that is, if the illuminance level signal input from the illuminance detection unit 5 exceeds the threshold value, no illumination is required. The lighting load 1 is not turned on. If the illuminance level signal falls below the threshold value while the timer 4a is counting the lighting holding time τ, the control unit 3 starts fade-in of the lighting load 1 from that point. At this time, the control unit 3 performs the fade-in speed during normal operation (= V (0.8))._0-100) Faster speed (= V (0.2)_0-100) To fade in.
[0029]
  As described above, in this embodiment, when there is a person in the detection area and the surroundings suddenly become dark during the counting of the lighting holding time τ, the lighting load is faster than usual. 1 can be faded in so that the light can be obtained as soon as it becomes dark, so that comfort can be obtained.
  As shown in FIG.Basic exampleThe same effect can be obtained by providing the illumination fixture 10 with the illuminance detection unit 5 similar to the present embodiment and performing the same control as the present embodiment for the configuration of 2.
[0030]
  (Embodiment2)
  The configuration of this embodiment isBasic example1 and the illustration and description thereof are omitted. In the present embodiment, the daytime mode in which the illumination load 1 is not turned on even when a human body detection signal is input from the human body detection unit 4, the output of the illumination load 1 is 100% of the rated (or maximum) output when the human body detection signal is input. The night mode that fades in and lights up, and when the human body detection signal is input, the output of the lighting load 1 is faded in to 100% of the rated (or maximum) output (fade in slower than the fade-in in the night mode) And it has a midnight mode that lights up. In each mode, the control unit 3 is provided with a clock function, and when the preset time is reached, the mode may be shifted from the daytime mode to the night mode or the midnight mode, or a mode switch is provided to change the mode. The time may be set or the embodiment1When the state in which the illuminance level signal is equal to or lower than the predetermined value continues for a certain period of time and the illuminance detection unit 5 described in the above is provided, the daytime mode may be shifted to the night mode.
[0031]
  Next, the operation of this embodiment will be described in detail with reference to FIG.
  First, when a human body detection signal is input from the human body detection unit 4 when the mode is set to the night mode, the control unit 3 changes the output of the illumination load 1 from a predetermined speed (= V ( 0.8)_0-100) And the lighting load 1 is turned on, and the timer 3a starts counting the lighting holding time τ. When this count is completed, the same speed as the fade-in (= V (0.8))_100-0) To start fading out. Here, when a human body detection signal is input from the human body detection unit 4 during the fade-out, the control unit 3 controls the normal speed (= V (0.8))._0-100) Faster speed (= V (0.2)_0-100) And fade-in to turn on the lighting load 1 at 100%.
[0032]
  When the human body detection signal is input from the human body detection unit 4 after the mode is changed from the night mode to the midnight mode, the control unit 3 continuously outputs the output of the illumination load 1 from 0% to 100% in 2.5 seconds. Speed to increase (= V (2.5)_0-100) And the lighting load 1 is turned on, and the timer 3a starts counting the lighting holding time τ. When this count is completed, the same speed as the fade-in (= V (2.5))_0-100) To start fading out. Here, when a human body detection signal is input from the human body detection unit 4 during the fade-out, the control unit 3 causes the normal speed (= V (2.5)_0-100), For example, the speed at which the output of the lighting load 1 is continuously increased from 0% to 100% in 1.5 seconds (= V (1.5)_0-100) And fade-in to turn on the lighting load 1 at 100%.
[0033]
  As described above, in the present embodiment, a more comfortable lighting environment can be obtained by fading in faster than the normal speed in each mode according to the time zone (mode corresponding to the time zone). Can do.
  (Embodiment3)
  The configuration of this embodiment isBasic example1 and the illustration and description thereof are omitted.Basic example1, when a human body detection signal is input from the human body detection unit 4 as shown in FIG. 12A, the control unit 3 controls the normal speed (= V (0.8))._0-100) Fade-in to light up lighting load 1 at 100% rated output and at the same speed (= V (0.8))_100-0), And if a human detection signal is input from the human body detection unit 4 during the fade-out, the speed is faster than the normal speed (= V (0.2)_0-100), And the lighting load 1 is fully lit at 100%.
[0034]
  On the other hand, in this embodiment, when the human body detection signal is input from the human body detection unit 4 when the maximum output of the illumination load 1 at the time of human body detection is 50% as shown in FIG. 3 is normal speed (= V (0.8)_0-100) Fades in to light up lighting load 1 at 50% output (dimming lighting) and at the same speed (= V (0.8))_100-0), And if a human detection signal is input from the human body detection unit 4 during the fade out, the speed is higher than the normal speed, and the lighting load 1 is continuously increased from 0% to 50% in 0.2 seconds. (= V (0.2)_0-50) To fade in, and the lighting load 1 is dimmed at 50%. Alternatively, as shown in FIG. 4C, when the maximum output of the illumination load 1 at the time of human body detection is set to 30%, when a human body detection signal is input from the human body detection unit 4, the control unit 3 performs normal speed (= V (0.8)_0-100) Fades in to light up lighting load 1 at 30% output (dimming lighting) and at the same speed (= V (0.8))_100-0), And if the human body detection signal is input from the human body detection unit 4 during the fade out, the speed is higher than the normal speed, and the lighting load 1 is continuously increased from 0% to 30% in 0.1 seconds. (= V (0.1)_0-30) To fade in, and the lighting load 1 is dimmed at 30%.
[0035]
  As described above, in the present embodiment, a more comfortable lighting environment is obtained by fading in faster than the normal speed at each output level in accordance with the output level when the lighting load 1 is turned on. be able to. In this embodiment, the external trigger for starting the fade-in during the fade-out is the human body detection signal from the human body detection unit 4, but the illuminance level signal input from the illuminance detection unit 5 is the external trigger, and the threshold is set. The valueBelowFade-in may be started when an illuminance level signal is input.
[0036]
  (Embodiment4)
  By the way, the embodiment3In the above, although fading-in is performed faster than usual regardless of the timing at which the human body detection signal is input from the human body detection unit 4 during fading out (the output of the lighting load 1 when the human body detection signal is input). The embodiment is characterized in that the speed at which the fade-in is performed again is changed according to the above timing (the output of the lighting load 1 when the human body detection signal is input). However, the configuration of this embodiment is the embodiment.3alikeBasic example1 and the illustration are omitted.
[0037]
  Next, the operation of this embodiment will be described in detail with reference to FIG. First, as shown in FIG. 13A, when the maximum output of the illumination load 1 at the time of human body detection is 100%, when a human body detection signal is input from the human body detection unit 4, the control unit 3 performs normal speed ( = V (0.8)_0-100) Fade-in to turn on the lighting load 1 with 100% output and at the same speed (= V (0.8))_100-0), And if a human detection signal is input from the human body detection unit 4 during the fade-out, the fade-in is performed faster than the normal speed and the lighting load 1 is turned on at 100%.Basic example1 orEmbodiment 3And in common. Here, the fade-in speed is changed depending on whether the output of the lighting load 1 at the time when the human body detection signal is input is 50% or more. For example, when the output of the lighting load 1 is 50% or more, the human body detection signal Is input, the controller 3 continuously increases the illumination load 1 from 0% to 100% in 0.2 seconds (= V (0.2)_0-100) To fade in. On the other hand, if the human body detection signal is input when the output of the lighting load 1 is 50% or less, the control unit 3 continuously increases the lighting load 1 from 0% to 100% in 0.4 seconds (= V ( 0.4)_0-100) To fade in.
[0038]
  Further, as shown in FIG. 5B, when the maximum output of the illumination load 1 at the time of human body detection is 50%, when the human body detection signal is input from the human body detection unit 4, the control unit 3 performs the normal speed ( = V (0.8)_0-100) Fades in to light up lighting load 1 at 50% output (dimming lighting) and at the same speed (= V (0.8))_100-0If the human body detection signal is input when the output of the lighting load 1 is 25% or more during the fading out, the control unit 3 is faster than the normal speed and the lighting load 1 is changed from 0% to 50%. % To increase continuously in 0.2 seconds (= V (0.2)_0-50) To fade in, and the lighting load 1 is dimmed at 50%. On the other hand, if the human body detection signal is input when the output of the lighting load 1 is 25% or less, the control unit 3 continuously increases the lighting load 1 from 0% to 50% in 0.3 seconds (= V ( 0.3)_0-50) To fade in.
[0039]
  Alternatively, as shown in FIG. 4C, when the maximum output of the illumination load 1 at the time of human body detection is set to 30%, when a human body detection signal is input from the human body detection unit 4, the control unit 3 performs normal speed (= V (0.8)_0-100) Fades in to light up lighting load 1 at 30% output (dimming lighting) and at the same speed (= V (0.8))_100-0If the human body detection signal is input when the output of the lighting load 1 is 15% or more during the fading out, the control unit 3 is faster than the normal speed, and the lighting load 1 is changed from 0% to 30%. Speed to continuously increase to 0.1% in 0.1 seconds (= V (0.1)_0-30) To fade in, and the lighting load 1 is dimmed at 30%. On the other hand, if a human body detection signal is input when the output of the illumination load 1 is 15% or less, the control unit 3 continuously increases the illumination load 1 from 0% to 30% in 0.15 seconds (= V ( 0.15)_0-30) To fade in.
[0040]
  Here, the smaller the output of the lighting load 1 when the human body detection signal is input during fading out, the slower the fade-in speed is. This is the output of the lighting load 1 when the human body detection signal is input. This is because the smaller the is, the fading-in is performed at a speed closer to the lighting (normal lighting) from when the lighting load 1 is turned off. In the present embodiment, two determination values are provided for the maximum output (100%, 50%, 30%) of the lighting load 1, but three or more determination values may be provided.
[0041]
  As described above, in the present embodiment, the output level when lighting the lighting load 1 and the timing when the human body detection signal is input from the human body detection unit 4 during the fade-out (the lighting load 1 when the human body detection signal is input) The speed at the time of fading in again is changed in accordance with the output of the output, so that a more comfortable lighting environment can be obtained. In this embodiment, the external trigger for starting the fade-in during the fade-out is the human body detection signal from the human body detection unit 4, but the illuminance level signal input from the illuminance detection unit 5 is the external trigger, and the threshold is set. The valueBelowFade-in may be started when an illuminance level signal is input.
[0042]
  (Embodiment5)
  The configuration of this embodiment isBasic example1 and the illustration and description thereof are omitted. In this embodiment, the embodiment2In the same way as in the daytime mode, when the human body detection signal is input from the human body detection unit 4, the lighting load 1 is not turned on. When the human body detection signal is input, the output of the lighting load 1 is faded to 100% of the rated (or maximum) output. Night mode for turning on and turning on, midnight mode for turning on and turning on the lighting load 1 to 30% of the rated output when the human body detection signal is input (fade in slower than the fade-in in the night mode) Have. In each mode, the control unit 3 is provided with a clock function, and when the preset time is reached, the mode may be shifted from the daytime mode to the night mode or the midnight mode, or a mode switch is provided to change the mode. The time may be set or the embodiment1When the state in which the illuminance level signal is equal to or less than a predetermined value is continued for a certain period of time by providing the illuminance detection unit 5 described above, the daytime mode may be shifted to the night mode.
[0043]
  Next, the operation of this embodiment will be described in detail with reference to FIG.
  First, when a human body detection signal is input from the human body detection unit 4 when the mode is set to the night mode, the control unit 3 changes the output of the illumination load 1 from a predetermined speed (= V ( 0.8)_0-100) And the lighting load 1 is turned on, and the timer 3a starts counting the lighting holding time τ. When this count is completed, the same speed as the fade-in (= V (0.8))_100-0) To start fading out. Here, when a human body detection signal is input from the human body detection unit 4 during the fade-out, the control unit 3 controls the normal speed (= V (0.8))._0-100) Faster speed (= V (0.2)_0-100) And fade-in to turn on the lighting load 1 at 100%.
[0044]
  When the human body detection signal is input from the human body detection unit 4 after the mode is changed from the night mode to the midnight mode, the control unit 3 continuously outputs the output of the illumination load 1 from 0% to 30% in 1.5 seconds. Speed to increase (= V (1.5)_0-30) And the lighting load 1 is turned on, and the timer 3a starts counting the lighting holding time τ. When this count is completed, the same speed as the fade-in (= V (1.5))_0-30) To start fading out. Here, when a human body detection signal is input from the human body detection unit 4 during the fade-out, the control unit 3 controls the normal speed (= V (1.5)._0-30), For example, the speed at which the output of the lighting load 1 is continuously increased from 0% to 30% in 0.8 seconds (= V (0.8)_0-30) To fade in, and the lighting load 1 is dimmed at 30%.
[0045]
  As described above, in the present embodiment, the speed at which the fade-in is performed again is changed according to the time zone (mode corresponding to the time zone) and the output level when the lighting load 1 is turned on. A simple lighting environment. In this embodiment, the external trigger for starting the fade-in during the fade-out is the human body detection signal from the human body detection unit 4, but the illuminance level signal input from the illuminance detection unit 5 is the external trigger, and the threshold is set. The valueBelowFade-in may be started when an illuminance level signal is input.
[0046]
  (Embodiment6)
  The configuration of this embodiment isBasic example1 and the illustration and description thereof are omitted. In this embodiment, while the lighting notification function is activated and the fade-out is temporarily stopped halfway, the lighting load 1 is lit at a constant output for a predetermined time (hereinafter referred to as notification time Ta). When a human body detection signal is input from the human body detection unit 4, the speed at which the fade-in is performed again according to the timing at which the human body detection signal is input (the elapsed time Tb of the notification time Ta when the human body detection signal is input). There is a feature in that it is changed.
[0047]
  Next, the operation of this embodiment will be described in detail with reference to FIG. Now, assuming that the notification time Ta is set to 5 seconds, when the human body detection signal is input when the elapsed time Tb is 2 seconds, the control unit 3 changes the illumination load 1 from 0% to 100%. Speed up continuously in 2 seconds (= V (0.2)_0-100) To fade in. On the other hand, when the human body detection signal is input when the elapsed time Tb is 4 seconds, the control unit 3 continuously increases the lighting load 1 from 0% to 100% in 0.4 seconds (= V ( 0.4)_0-100) To fade in. Here, the longer the elapsed time Tb when the human body detection signal is input, the slower the fade-in speed. This is because the elapsed time Tb when the human body detection signal is input is longer. It is considered that the person entered the detection area for the first time while the notification function was working, and such a situation is similar to turning on the lighting load 1 from the off state (0%), This is because it is preferable to fade in at a speed close to the normal speed.
[0048]
  As described above, in this embodiment, the speed at which the fade-in is performed again is changed according to the timing at which the human body detection signal is input (the elapsed time Tb of the notification time Ta at the time when the human body detection signal is input). A more comfortable lighting environment can be obtained.
[0049]
【The invention's effect】
  As described above, according to the present invention,There is an effect that a comfortable light can be provided by changing the slope of the fade-in when the lighting load is turned on according to the situation.
[Brief description of the drawings]
[Figure 1]Basic example of the present invention1 is a block diagram showing 1. FIG.
FIG. 2 is an explanatory diagram for explaining the operation described above.
FIG. 3 is an explanatory diagram for explaining the operation described above.
FIG. 4 is an explanatory diagram for explaining the operation of a conventional example compared with the above.
[Figure 5]Basic example2 is a block diagram showing 2. FIG.
[Fig. 6]Basic exampleFIG.
FIG. 7 is an explanatory diagram for explaining the operation described above.
[Fig. 8]Of the present inventionEmbodiment1FIG.
FIG. 9 is an explanatory diagram for explaining the operation described above.
FIG. 10 is a block diagram showing another configuration of the above.
FIG. 11 Embodiment2It is explanatory drawing for demonstrating operation | movement of.
FIG. 12 is an embodiment.3It is explanatory drawing for demonstrating operation | movement of.
FIG. 13 is an embodiment.4It is explanatory drawing for demonstrating operation | movement of.
FIG. 14 is an embodiment.5It is explanatory drawing for demonstrating operation | movement of.
FIG. 15 is an embodiment.6It is explanatory drawing for demonstrating operation | movement of.
FIG. 16 is an explanatory diagram for explaining the operation of a conventional example.
FIG. 17 is an explanatory diagram for explaining the operation of another conventional example.
[Explanation of symbols]
  1 Lighting load
  2 Load control unit
  3 Control unit
  4 Human body detector
  AC commercial AC power supply

Claims (7)

Human body detection means for outputting a human body detection signal by detecting lighting load, presence / absence or movement of a person within the detection range, ambient illuminance detection means for outputting an illuminance level signal corresponding to the ambient illuminance, and the above human body detection Control means for varying the amount of power supplied from the external power source to the lighting load according to the detection result by the means and the ambient illuminance detection means, and for turning on, turning off, and dimming the lighting load. If the external trigger signal is input when the output level of the lighting load is gradually reduced and the fade load is being performed , the lighting load is reduced according to the detection result of the human body detection means and the ambient illuminance detection means. A lighting device characterized in that the lighting load is faded in and turned on with a slope larger than a predetermined slope when fading in . Human body detection means for outputting a human body detection signal by detecting lighting load, presence / absence or movement of a person within the detection range, ambient illuminance detection means for outputting an illuminance level signal corresponding to the ambient illuminance, and the above human body detection Control means for varying the amount of power supplied from the external power source to the lighting load according to the detection result by the means and the ambient illuminance detection means, and for turning on, turning off, and dimming the lighting load. The predetermined lighting holding time is counted from the time when the human body detection signal is input, and the lighting load is turned on at a predetermined output level during the counting, and the lighting holding time is being counted. Sometimes when an external trigger signal is input, the inclination is larger than a predetermined inclination when the lighting load is faded in according to the detection result by the human body detection means and the ambient illuminance detection means. Lighting apparatus characterized in that light the fade-in serial lighting load. The lighting device according to claim 1, wherein the human body detection signal is the trigger signal . A lighting fixture comprising at least the lighting load, a control means and a receiving means for receiving a remote control signal; and at least the detection means and a transmitter for transmitting the remote control signal corresponding to a detection result by the detection means, 4. The lighting device according to claim 3 , wherein a remote control signal is used as the trigger signal . 3. The illumination apparatus according to claim 2, wherein the illuminance level signal that falls below a predetermined level is used as the trigger signal . The lighting device according to any one of claims 1 to 5, wherein the control means changes a slope of fade-in when the lighting load is turned on according to a time zone . 2. The control means according to claim 1 , wherein the slope when fading in when the trigger signal is input increases as the output level of the illumination load when the trigger signal is input is lower. The illuminating device in any one of -5 .

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