JP3608326B2 - Hot wire automatic switch - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hot-wire automatic switch that detects the presence or absence of a person by detecting heat rays radiated from a human body and automatically turns on / off a lighting load.
[0002]
[Prior art]
Conventionally, this type of hot-wire automatic switch, such as a pyroelectric infrared sensor as a heat ray sensor for detecting heat rays (far infrared rays) from the human body, is a differential type that can output only when the received heat dose changes. Often, a hot wire sensor is used. When lighting the lighting load by detecting the presence of a person with this type of heat ray sensor, the predetermined holding time after the output of the heat ray sensor is obtained must be timed so as to maintain the lighting load in the lighting state. is there. Further, this time period is retriggerable, and the holding time is extended if the presence of a person is detected during the holding time.
[0003]
[Problems to be solved by the invention]
By the way, this type of heat ray sensor generates an output when the received heat dose changes, so even if there is a person in the preset detection area, if the person does not move, detection by the heat ray sensor Will not be able to. In other words, even if the time limit for maintaining the lighting state of the lighting load is performed as described above, if the person in the detection area stops moving, the lighting load is turned off with the expiration of the holding time despite the presence of the person. This is inconvenient.
[0004]
The present invention has been made in view of the above-mentioned reasons, and its purpose is to provide a hot-wire automatic switch which can avoid inconvenience due to sudden turn-off of a lighting load by giving a notice before the holding time expires. Is to provide.
[0005]
[Means for Solving the Problems]
The invention according to claim 1 generates a detection signal indicating the presence of a person based on a change in a heat ray sensor that detects a heat ray emitted from a human body and a heat dose incident on the heat ray sensor from a preset detection area. Human detection means;A brightness sensor that detects ambient brightness;Timer means for timing a predetermined holding time and a notice time shorter than the holding time every time a detection signal is generated;During the period from when the ambient brightness detected by the brightness sensor falls below the specified lighting value until it exceeds the specified lighting value that is brighter than the lighting valueWhen the detection signal is generated, the lighting load is turned on with a predetermined light output.AndWhen the holding time expires, the light output of the lighting loadUp to the state before the detection signal is generatedReduceThe lighting load is turned off regardless of the presence or absence of a detection signal during the period from when the ambient brightness exceeds the turn-off value to the turn-on value or less.A lighting control means and a notice means for notifying that the holding time is about to expire when the notice time expires during lighting of the illumination load due to the generation of the detection signal are provided. According to this configuration, since the notice means notifies that the holding time is about to expire before the holding time expires, a detection signal is generated by the movement of the person at the time of the notice and the holding time is extended. The lighting load can be kept on and there is no inconvenience that the lighting load suddenly turns off.Moreover, since the illumination load is turned off regardless of the presence or absence of a detection signal in the daytime when the brightness detected by the brightness sensor is equal to or greater than the turn-off value, useless power consumption does not occur.
[0007]
Claim 2The invention ofClaim 1In this invention, the lighting control means holds the illumination load during the period from when the ambient brightness detected by the brightness sensor becomes lower than the lighting value until it becomes higher than the lighting value, excluding the holding time. The light is dimmed with less light output than time. In this configuration, during the period from the ambient brightness below the lighting value to the lighting off value, it is dimmed even when no people are detected, so it can function as a night light, gate lights, stairs In a place where it is desirable to keep the lamp lit even when there are no people, such as a lamp or a corridor lamp, the functions of the main lamp and the night lamp can be combined with one lighting load.
[0008]
Claim 3The invention ofInvention of Claim 1In the above, a warning light is used so that the light output of the illumination load is higher than the light output after expiration of the holding time and lower than before the expiration of the warning time. According to this configuration, by changing the light output of the illumination load, it is notified that the holding time is about to expire, so there is no need to provide a separate notification means.
[0009]
Claim 4The invention ofInvention of Claim 1In the above, what is acoustically notified is used as the notice means. According to this configuration, it is possible to notify the expiration of the holding time without changing the light output of the lighting load, and thus it is possible to make a notification without changing the light output of the lighting load. That is, there is no sense of incongruity caused by changing the brightness.
[0010]
Claim 5The invention ofInvention of Claim 1In FIG. 1, at least a heat ray sensor and a person detecting means are provided, and a child device that generates a detection signal when the presence of a person is detected can be connected. According to this configuration, since a detection area can be formed using a plurality of heat ray sensors, it is possible to set a wide range of detection areas or to set a detection area having a complicated shape.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
(Embodiment 1)
In this embodiment, as shown in FIG. 1A, a pyroelectric infrared sensor (hereinafter referred to as a pyroelectric sensor) 1 is used as a heat ray sensor for detecting a heat ray from a human body, and the output of the pyroelectric sensor 1 is amplified. After being amplified by the unit 11, it is inputted to the microcomputer 2. The microcomputer 2 performs A / D conversion on the output of the amplifying unit 11, and further determines the presence or absence of a person in a preset detection area based on the output value of the pyroelectric sensor 1. Here, the detection area is set by an optical element such as a lens, a mirror, and a light shielding plate arranged in the incident path of the heat ray to the pyroelectric sensor 1. Inside the microcomputer 2, when it is determined that a person is present in the detection area based on the output of the pyroelectric sensor 1, a detection signal is generated.
[0012]
A brightness sensor 3 that detects ambient brightness using CdS or the like is also connected to the microcomputer 2. The output of the brightness sensor 3 is A / D converted, and the ambient brightness detected by the brightness sensor 3 is compared with the extinction value and the lighting value set by the operating illuminance adjustment unit 4. The extinguishing value is set several times (about four times) the lighting value. Here, the period from when the ambient brightness detected by the brightness sensor 3 becomes the lighting value or less to the lighting value or more is a dark period, and the period from the lighting value or more to the lighting value or less Is called the light period. That is, the extinction value is a value set to the ambient brightness when lighting is unnecessary at dawn, for example, and the lighting value is set to the ambient brightness when illumination is required in the evening, for example . The operating illuminance adjusting unit 4 is composed of a changeover switch or a variable resistor, and adjusts the extinction value and the lighting value stepwise or continuously. Although the turn-off value and the turn-on value may be set separately, since the setting operation is troublesome, the setting operation is performed so that the turn-off value and the turn-on value maintain a constant difference or a constant magnification.
[0013]
The microcomputer 2 has a function of turning on and off the bidirectional three-terminal thyristor (triac) 13 via the drive unit 12. The triac 13 has a power supply terminal F for connecting a commercial power supply AC.₁₁, F₁₂And a load terminal F for connecting the lighting load 5₁₃, F₁₄(Power terminal F₁₁And load terminal F₁₄The conduction angle is controlled by the microcomputer 2 to adjust the power supplied to the illumination load 5 and change the light output. Here, a case where the power supplied to the incandescent bulb as the illumination load 5 is controlled by the triac 13 is illustrated, but a discharge lamp can be used as the illumination load 5 if a required lighting circuit is provided.
[0014]
By the way, the most basic operation of the microcomputer 2 is the pyroelectric sensor in the period from when the ambient brightness detected by the brightness sensor 3 becomes lower than the lighting value to when it becomes higher than the lighting value, that is, in the dark period. When a person is detected based on the change in the heat dose incident on 1 (that is, when a detection signal is generated), the lighting load 5 is turned on. Timed by the configured timer means. In the light period, the illumination load 5 is kept off regardless of whether the pyroelectric sensor 1 detects a person. That is, the illumination load 5 is turned off during bright daytime.
[0015]
The timer means limits a predetermined holding time and a notice time shorter than the holding time each time a detection signal is generated, and is configured to be retriggerable. That is, if a detection signal is generated before the hold time expires, the time limit between the notice time and the hold time is redone, and the notice time expires after the notice time elapses from the latest detection signal. If no detection signal is generated after expiration, the retention time expires after the retention time has elapsed. The advance notice time and holding time can be adjusted by the operation holding time setting unit 14, and the operation holding time setting unit 14 is configured by a changeover switch or a variable resistor. The operation hold time setting unit 14 sets two types of time, a notice time and a hold time. Generally, the time difference between the notice time and the hold time may be a constant time of about several seconds, so one operation with a fixed time difference is performed. Both hours can be set in the department.
[0016]
In the present embodiment, the illumination load 5 can be turned on or off regardless of the output of the pyroelectric sensor 1, and can be turned on or off in conjunction with the output of the pyroelectric sensor 1. An operation changeover switch 15 is also provided for selecting the above. Further, an operation indicator lamp 16 made of a light emitting diode for displaying whether or not a detection signal is generated is also provided. The power supply for the internal circuit is the power supply terminal F₁₁, F₁₂It is obtained by a stabilized DC power supply 17 that receives a commercial power supply AC connected to and outputs a constant DC voltage. The microcomputer 2 is also connected with a reset circuit 18 formed of an integrated circuit for resetting when the power is turned on.
[0017]
As is apparent from the above description, a person detecting means for generating a detection signal when it is determined that a person is present in the detection area based on the output of the pyroelectric sensor 1, a timer means for timing a notice time and a holding time, The lighting control means for controlling the lighting state of the lighting load 5 is realized by the microcomputer 2.
Next, the operation of the circuit shown in FIG. In the present embodiment, the illumination load 5 is maintained in the off state regardless of the presence or absence of the detection signal in the bright period Pb (FIG. 1 (b)), such as daytime and bright surroundings. As shown in b), in a dark period Pd where the surroundings are dark such as at night, the time t₁When a detection signal is detected due to human detection, the lighting load 5 is first turned on with a light output of 15% at the time of full lighting (generally rated lighting), and then the light output is gradually increased to full lighting with the passage of time. Increase to. Time t₁To time t₂The time until all the lights are turned on is the holding time T described above.₂The light output is changed at a speed that does not feel glare. By so-called soft-starting the lighting load 5 in this way, the human eye is adapted to avoid feeling glare when the lighting load 5 is turned on. In addition, by soft-starting, the rush current does not flow through the incandescent light bulb as the lighting load 5, and the life of the lighting load 5 can be extended.
[0018]
Time t after the lighting load 5 is turned on₃Notice time T₁When the lamp expires, the light output is reduced to 50% and the notice light is dimmed (dimmed lighting). This is the holding time T₂At the time t₄Holding time T₂When is expired, the illumination load 5 is turned off. However, as described above, since the timer means is retriggerable, the holding time T₂Medium (actually at time t₂~ Time t₄When the detection signal is generated during the period of time), the lighting load 5 is fully turned on, and the subsequent notice time T₁If there is no detection signal between₁It will be dimmed after the expiry date. As a result, if a detection signal is generated during the period when the lighting load 5 is fully lit, the fully lit state is changed to the notice time T₁If the detection signal is generated during the period when the illumination load 5 is the warning dimming, it will return to the fully lit state. In short, notice time T₁Holding time T from expiration of₂Until the expiration of, the advance light diminishes to notify that the illumination load 5 will be extinguished soon. Therefore, if the person in the detection area moves during this period, the illumination load 5 is kept in the lit state. In this way, it is possible to prevent the lighting load 5 from turning off suddenly, for example, when using the toilet or standing up. If the lighting state of the lighting load 5 is to be maintained, a detection signal is generated if the lighting load 5 moves within the detection area during the advance dimming, and the lighting load 5 is kept on.
[0019]
In the above example, the light output of the illumination load 5 is switched to 15%, 50%, and 100% (rated lighting), but this is an example, and each value of the light output is appropriately selected as necessary. Is done. Also notice time T₁The reason for changing from full lighting to 50% lighting due to the expiration of is to make sure that the notice is recognized with a difference in the amount of light that is sufficiently visually recognized, and need not necessarily be 50%. Absent. Similarly, when the lighting load 5 is turned on, it may be set to an appropriate light output instead of 100% lighting.
[0020]
By the way, the hot-wire automatic switch Y mentioned above is comprised so that it may attach to a ceiling as shown in FIG. This is to make the detection area substantially coincide with the light irradiation range by the illumination load 5. Specifically, it can be attached to the ceiling by using the case 20 as shown in FIG.
The case 20 includes a disk-shaped case main body 21 and a cover 22 coupled to the center of the upper surface of the case main body 21. An annular surrounding wall 21a is formed at the center of the upper surface of the case body 21, and four coupling pieces 21b are erected on the upper edge of the surrounding wall 21a. Each coupling piece 21 b is formed with a coupling hole 21 c, and the coupling hole 21 c engages with the coupling protrusion 22 a projecting from the side surface of the cover 22, whereby the cover 22 is coupled to the case body 21. A groove 22b that fits into the coupling piece 21b is formed on the side surface of the cover 22 so that the side surface of the cover 22 and the coupling piece 21b are substantially flush with the coupling protrusion 22a engaged with the coupling hole 21c. It is.
[0021]
The case 20 is fixed to the ceiling by using a pair of mounting brackets 30 coupled to the case 20 or using box screws that are screwed into an embedding box for wiring equipment. The mounting bracket 30 includes a column body 31 having a substantially U-shaped horizontal section that is detachably fitted in a mounting groove 23 provided in a peripheral portion of the case body 21, and a vertical tightening screw 32 is rotated on the column body 31. It is held freely. A clamping piece 33 is screwed onto the tightening screw 32 so that the clamping piece 33 can be moved up and down by rotation of the tightening screw 32. A pull-out notch 31a is formed in the upper side wall of the column 31. When the clamping screw 32 is rotated to move the clip piece 33 upward, the clip piece 33 is finally inserted into the pull-out notch 31a. It is.
[0022]
Accordingly, when the tightening screw 32 is rotated so as to move the pinching piece 33 downward with the mounting bracket 30 fixed to the case main body 21, the pinching piece 33 comes out of the pull-out notch 31a and the diameter direction of the case main body 21 is reached. The distance between the clip piece 33 and the case main body 21 is reduced. Accordingly, the clamping piece 33 is inserted into the pull-out notch 31a, the mounting bracket 30 is inserted into the through hole provided in the ceiling plate, and the tightening screw 32 is rotated with the case body 21 in contact with the ceiling surface. If the pinching piece 33 is pulled downward, the case body 21 and the pinching piece 33 hold the ceiling plate around the through hole, and the case 20 can be fixed to the ceiling.
[0023]
On the other hand, when an embedded box such as a switch box for wiring equipment is installed on the ceiling, a box screw inserted into a box hole 24 provided in the peripheral portion of the case body 21 can be screwed into the embedded box. In this case, the case 20 can be fixed to the ceiling.
By the way, a window hole 25 opening in a circular shape is formed near the center of the part surrounded by the surrounding wall 21a of the case body 21. A spherical rotating case 41 in which a rotating body 41a and a lens 41b each formed in a hemispherical shape are coupled by a lens frame 41c is mounted in the window hole 25. In the rotating case 41, a pair of projecting pieces 41d projecting from the lens frame 41c are respectively inserted into a pair of groove portions 25a formed on the inner peripheral surface of the window hole 25, and the projecting piece 41d is used as an axis in the groove portion 25a. It is possible to rotate and to slide the projecting piece 41d in the groove 25a. Therefore, it is possible to turn the rotating case 41 in a desired direction. The rotating case 41 houses a printed circuit board 42 on which the pyroelectric sensor 1 and the brightness sensor 3 are mounted.
[0024]
The diameter of the rotating case 41 is smaller than the diameter of the window hole 25 and is mounted so as not to drop downward from the case body 21. A holding plate 44 fixed to the case main body 21 by a pair of fixing screws 43 is disposed on the upper surface side of the rotating case 41, and a support bar urged downward by a spring 45 with respect to the holding plate 44. 46 elastically contacts the upper surface of the rotating case 41 via the O-ring 47. Therefore, if the rotating case 41 is rotated while being pushed upward, the frictional force with the peripheral portion of the window hole 25 is reduced and the rotating case 41 can be easily rotated, and the O-ring 47 is provided. Inadvertent misalignment of the rotating case 41 is prevented by the frictional force.
[0025]
In the case 20, two printed circuit boards 26a and 26b mounted with other circuit portions excluding the pyroelectric sensor 1 and the brightness sensor 3 are accommodated in a vertically arranged form on the upper surface of the upper printed circuit board 26a. A terminal portion 27 as a quick connection terminal is mounted. That is, the terminal portion 27 houses a lock spring 27b formed by bending a strip having springiness in a terminal plate 27a having a substantially U-shaped horizontal section, and holds the electric wire between the terminal plate 27a and the lock spring 27b. is there. The electric wire connected to the terminal portion 27 is inserted into the electric wire insertion port 27c formed on the upper wall of the cover 22, and in order to remove the electric wire connected to the terminal portion 27, it comes into contact with each pair of lock springs 27b. The unlocking button 27d provided is pressed to push the lock spring 27b so as to increase the distance between the terminal plate 27a and the lock spring 27b. If the electric wire is pulled out in this state, the electric wire can be easily removed. For the pressing operation of the unlock button 27d, a tool such as a tip of a minus driver may be used, and the tool may be inserted into a tool insertion port 27e provided on the upper wall of the cover 22.
[0026]
A terminal cover 28 that can cover the electric wire insertion port 27c is detachably fitted to the upper surface of the case 20. The terminal cover 28 has an engaging leg 28 a that protrudes downward, and the terminal cover 28 is fixed to the case 20 by engaging the engaging leg 28 a with an engaging hole 22 c provided in the cover 22. A decorative plate 29 having an opening window 29a at the center is fitted on the lower surface side of the case body 21. The decorative plate 29 is fixed to the case main body 21 by engaging a claw 29b provided on the peripheral portion with the peripheral portion of the case main body 21, and hides the heads of the tightening screw 31 and the box screw.
[0027]
(Embodiment 2)
This embodiment is similar to the first embodiment in that the holding time T₂Is different from the first embodiment in that the illumination load 5 is lit at a predetermined light output even when no detection signal is generated during the dark period Pd. For example, the light output of the illumination load 5 during the dark period Pd is set to 15% of the total lighting. By such an operation, the illumination load 5 can be dimmed at night as a night light, and the illumination load 5 can be fully lit only when a person approaches. That is, it does not become dark at night, and it is possible to reduce power consumption as compared with the case where all lights are turned on.
[0028]
With this configuration, in this embodiment, as shown in FIG. 4, the illumination load 5 is turned off during the bright period Pb such as daytime, and the time t is displayed during the dark period Pd such as nighttime.₀When the brightness falls below the lighting value, the light is dimmed at a light output of 15%. In addition, a person is detected during the dimming period and the time t₁When the detection signal is generated, the lighting load 5 is fully lit and then the notice time T₁Elapses and time t₃Then, as in the first embodiment, the noticeable light is diminished at a light output of 50%. Also, the holding time T₂Elapses and time t₄The light output returns to 15%. In other words, it is possible to provide two functions of the main illumination and the nightlight in a gate lamp, a hallway lamp, and the like by one illumination load 5.
[0029]
By the way, in this embodiment, since the illumination load 5 is lit during the dark period Pd, the extinction value and the lit value are set to L.₁, L₂Then, the ambient brightness detected by the brightness sensor 3 changes as shown in FIG. That is, the ambient brightness is the lighting value L₂When the lighting period 5 decreases to the dark period Pd, the brightness increases due to the lighting load 5 being turned on. However, the extinction value L₁Is the lighting value L₂(For example, the extinction value L₁80 lux, lighting value L₁Is set to 20 lux), the brightness is turned off L₁And the dark period Pd can be maintained. As described above, in order to maintain the dark period Pd, the extinction value L is considered in consideration of the change in brightness associated with the lighting load 5 being turned on.₁And lighting value L₂It is necessary to set a difference between the light-off value L in order to cope with changes in the specifications and installation conditions of the lighting load 5.₁And lighting value L₂The difference is set to be large enough to allow for a margin. Thus, the extinction value L₁And lighting value L₂By making the difference sufficiently large, even if the illumination load 5 is turned on during the dark period Pd, the brightness is turned off.₁Thus, the inconvenience that the lighting load 5 is turned off again can be avoided.
[0030]
However, the extinction value L₁Since it is necessary to set to a large value, there is a case where the lighting load 5 is delayed and the power is consumed wastefully. Therefore, the brightness at the time when the illumination load 5 is turned on at the start of the dark period Pd is stored in the microcomputer 2, and the required margin M is added to the stored brightness as shown in FIG. 5 (b). Value is extinguished value L₁It is desirable to set automatically as With this configuration, the lighting value L₂If only is set, the extinction value L depends on the specifications of the lighting load 5 and the installation conditions.₁Is automatically set and the extinction value L₁And lighting value L₂There is no need to allow for the difference between₁Can be set as dark as possible. As a result, the time at which the illumination load 5 is extinguished at dawn can be advanced, and as a result, useless power consumption can be suppressed. Other configurations and operations are the same as those of the first embodiment.
[0031]
(Embodiment 3)
In the first embodiment, the holding time T₂Holding time T by dimming the lighting load 5 before the expiration of₂However, in this embodiment, as shown in FIGS. 6 and 7, the buzzer 6 is provided to provide an acoustic warning. As shown in FIG. 7, the buzzer 6 is mounted on the lower surface side of the lower printed circuit board 26 b accommodated in the case 20, and a plurality of sound output holes 20 a are formed in a portion corresponding to the buzzer 6 on the lower wall of the case 20. Is made so that the sound of the buzzer 6 can be heard easily.
[0032]
In the present embodiment, as shown in FIG.₁When the time expires, the buzzer 6 sounds and the holding time T₂Notify that the expiration of is near. For the lighting load 5, the notice time T₁Even if the period of time expires, the light is not dimmed and the state of full lighting (or predetermined light output) is continued. That is, in the configuration of the first embodiment, the holding time T₂When the lighting load 5 expires, the illumination load 5 is dimmed in advance from the fully lit state, and then returns to the fully lit state if the detection signal is generated again. However, in this embodiment, the light output changes. Holding time T without changing light output₂Can be extended.
[0033]
In the present embodiment, the buzzer 6 is exemplified as a means for acoustically notifying, but a speaker may be provided so as to notify with a synthesized sound or a melody sound. Other configurations and operations are the same as those of the first embodiment.
(Embodiment 4)
As shown in FIG. 9, in the present embodiment, in the configuration of the second embodiment, a connection terminal F for enabling connection of an external switch SW (see FIG. 10) composed of a push button switch for instructing turning off is provided.₁₅, F₁₆And a push button input detection unit 19a and a current limiting circuit 19b for detecting the operation of the external switch SW. That is, the push button input detection unit 19a is connected to the connection terminal F.₁₅, F₁₆Is detected, and it is determined whether or not the external switch SW has been pressed in accordance with the voltage value, and the determination result is given to the microcomputer 2, and the connection terminal F₁₅, F₁₆Thus, the current limiting circuit 19b is provided so that the current flowing through the external switch SW does not become excessive. On the other hand, the external switch SW is connected to the connection terminal F in response to the pressing operation.₁₅, F₁₆By switching the Zener diode connected between₁₅, F₁₆It is comprised so that the voltage between may be changed. Connection terminal F₁₅, F₁₆As shown in FIG. 11, it is mounted on the upper surface side of the upper printed circuit board 26a.
[0034]
The external switch SW is provided for instructing the microcomputer 2 to enter the forced turn-off mode by pressing. As shown in FIG.₅When the forced turn-off mode is instructed at, the illumination load 5 that is turned off is forcibly turned off. With this function, when there is less traffic at night and it is not necessary to turn on the illumination load 5, the illumination load 5 can be forcibly turned off, and as a result, useless power consumption can be suppressed. Even when the illumination load 5 is turned off in the forced turn-off mode, a person is detected by the pyroelectric sensor 1 and the time t₆If a detection signal is generated, the lighting load 5 is fully lit and the notice time T₁And holding time T₂Do the time limit. This is convenient because the illumination load 5 can be automatically turned on when a person passes even after the forced light-off mode is set. When the lighting load 5 is turned on after the transition to the forced extinguishing mode, the holding time T₂After the expiration of, the lighting load 5 is turned off instead of dimming (notice dimming). The forced turn-off mode is automatically canceled when the ambient brightness reaches the turn-off value and the light period Pb is reached. Therefore, no special operation is required to cancel the forced light-off mode. In the forced turn-off mode, the illumination load 5 may be turned off with a smaller light output than when the light is turned off instead of turning off the light load 5 completely. Other configurations and operations are the same as those of the second embodiment.
[0035]
(Embodiment 5)
In the fourth embodiment, the forced turn-off mode is selected by the external switch SW. However, in the present embodiment, the predetermined operation effective time T from the start of the dark period Pd is used without using the external switch SW.₃After the elapse of time (see FIG. 14), the mode is automatically shifted to the forced extinction mode. That is, as shown in FIG.₀When the dark period Pd is reached, the microcomputer 2 operates the operation effective time T.₃The time limit of the operation starts₃During this period, the light is dimmed at 15% light output, and if a detection signal is generated, the notice time T₁And holding time T₂The operation is performed in the same manner as in the second embodiment. On the other hand, the operation valid time T₃Is completed, the lighting load 5 is turned off by switching to the forced light-off mode, or the light load is turned on with a light output smaller than that in the dimming lighting (lighting period T in FIG. 14).₃(Indicated by a broken line after elapse of time). Similarly to the fourth embodiment, when a detection signal is generated in the forced turn-off mode, the lighting load 5 is turned on until the holding time expires, and thereafter turned off (or dimmed at a low level).
[0036]
Such an operation eliminates the need to operate the external switch SW, improving usability. This is particularly convenient in places where it is necessary to shift to the forced extinction mode every night. The forced turn-off mode is released in the same manner as in the fourth embodiment, and is automatically released when the light period Pb is entered.
By the way, the operation effective time T₃Is variable by the time setting unit 7 shown in FIG. 13, and the time setting unit 7 is constituted by a variable resistor. Thus, the operation effective time T₃Can be adjusted, the operation effective time T according to the conditions such as the installation location of the lighting load 5₃Can be set appropriately. Other configurations and operations are the same as those of the fourth embodiment.
[0037]
(Embodiment 6)
In the present embodiment, the transition to the forced turn-off mode is determined by time. That is, as shown in FIG. 15, the time display unit 8a and the time setting unit 8b are provided, and the time t set by the time setting unit 8b in the dark period Pd as shown in FIG.₅When it becomes, it will shift to forced extinction mode. The time display unit 8a is configured using a liquid crystal display or a light emitting diode display, and the time setting unit 8b is provided with a plurality of switches. When the mode is switched to the forced extinction mode, the illumination load 5 is extinguished or dimmed in the same manner as in the fourth embodiment, and if the detection signal is generated during the forced extinction mode, the illumination load 5 is fully illuminated until the holding time expires. Canceling the forced light-off mode is the same as in the fourth embodiment, and the forced light-off mode is automatically canceled by shifting to the light period Pb. With this configuration, the operation of the external switch SW becomes unnecessary, and usability is improved. This is particularly convenient in places where it is necessary to shift to the forced extinction mode every night. Other configurations and operations are the same as those of the fourth embodiment.
[0038]
(Embodiment 7)
As shown in FIG. 17, this embodiment is obtained by omitting the brightness sensor 3 and the operating illuminance adjustment unit 4 in the configuration of the second embodiment, and the person in the detection area is independent of the surrounding brightness. The illumination load 5 is controlled only according to whether or not there is. That is, the operation related to the ambient brightness is omitted from the configuration of the second embodiment, and the lighting load 5 is always dimmed and the holding time T is generated when the detection signal is generated.₂Only lights up. Here, as in the second embodiment, the notice time T₁Only after all the lights are turned on, the notice light is turned on, or the holding time T as in the third embodiment₂It is possible to appropriately select whether to light all during the period. The light output at the time of dimming lighting is set higher than that of the second embodiment.
[0039]
This embodiment is used, for example, for the purpose of illuminating an exhibit in an art museum or an exhibition hall so that the light is dimmed when a person is not in the vicinity and is fully lit only when there is a person. In this way, by changing the amount of illumination light, it is possible to enhance the effect of attracting human eyes. Further, when there is no person, power consumption can be suppressed by reducing the light output of the illumination load 5. Other configurations and operations are the same as those of the second embodiment.
[0040]
(Embodiment 8)
In the present embodiment, the holding time T₂The light output at the time of dimming lighting other than the above can be set. FIG. 18 shows an example in which the light control level setting unit 9 for adjusting the light output at the time of dimming lighting is provided in FIG. It is shown. As the dimming level setting unit 9, one that switches in stages using a changeover switch or one that continuously adjusts using a variable resistor is used.
[0041]
According to this configuration, the light output at the time of dimming lighting can be adjusted according to the rating of the lighting load 5, the installation conditions of the lighting load 5 or the surrounding environment, and the convenience is enhanced. Note that the technical idea of the present embodiment is also applicable to the configuration of the seventh embodiment.
(Embodiment 9)
In the present embodiment, the notice time T in the configuration of the first embodiment₁And holding time T in the configuration of the third embodiment₂The light output when the lighting load 5 corresponding to is turned on is changed according to the ambient brightness. In other words, the darker the surroundings, the lower the light output when the illumination load 5 is turned on. For example, assuming that the ambient brightness changes as shown in FIG. 19A and the detection signal is generated as shown in FIG. 19B, the lighting load 5 is turned on during the above period. The optical output is set as shown in FIG.
[0042]
By such an operation, the difference in brightness before and after detecting a person can be reduced, the adaptation of the eyes to the change in brightness is facilitated, and the degree of glare is reduced. In addition, the power consumption is reduced as compared with the case where the lighting load 5 is always turned on when the lighting load 5 is turned on. Here, in this embodiment, the soft start function may be omitted. Other configurations and operations are the same as those of the first embodiment.
[0043]
(Embodiment 10)
In this embodiment, as shown in FIGS. 20 and 21, in the configuration of the first or second embodiment, a connection terminal F for enabling connection of the slave unit X (see FIG. 22).₁₇, F₁₈Is provided. This configuration is basically the same as that provided with the external switch SW, and the connection terminal F₁₇, F₁₈A child device input detector 19c that detects the operation of the child device X by a voltage change between₁₇, F₁₈And a current limiting circuit 19d for limiting the current flowing through the slave unit X through an excessive amount.
[0044]
The subunit X includes a pyroelectric sensor and a human detection unit that generates a detection signal based on the output of the pyroelectric sensor, and includes a case having the same configuration as the case 20. When a detection signal is generated in the slave unit X, a connection terminal F is used by using a Zener diode provided in the slave unit X.₁₇, F₁₈The slave unit input detector 19c that detects this voltage change gives a detection signal to the microcomputer 2. This detection signal is logically summed with the detection signal from the hot wire sensor 1 and used for processing in the microcomputer 2. In short, this is equivalent to using the pyroelectric sensors in parallel. By using the slave unit X in this way, it is possible to widen the detection area or to form a complex detection area by combining the slave units X. Other configurations and operations are the same as those in the first and second embodiments.
[0045]
【The invention's effect】
Invention of Claim 1The personA heat detection sensor for detecting a heat ray emitted from the body, a human detection means for generating a detection signal indicating the presence of a person based on a change in a heat dose incident on the heat ray sensor from within a preset detection area, A brightness sensor for detecting brightness, timer means for timing a predetermined holding time and a notice time shorter than the holding time each time a detection signal is generated, and the ambient brightness detected by the brightness sensor is stipulated. If a detection signal occurs during the period from when the value falls below the specified value to the specified turn-off value brighter than the lighting value, the lighting load is turned on at a predetermined light output, and when the holding time expires, the light output of the lighting load is detected. The lighting load is turned off regardless of the presence or absence of a detection signal during the period from when the ambient brightness exceeds the turn-off value to the turn-on value or less. And a notice means for notifying that the holding time is about to expire when the notice time expires while the lighting load is lit by the generation of the detection signal, and the holding time expires before the holding time expires. Because the notice means that the approach is approaching, the detection signal is generated by the movement of the person at the time of the notice, the holding time can be extended and the lighting load can be kept on, and the lighting load turns off suddenly Such an inconvenience does not occur. Moreover, since the illumination load is turned off regardless of the presence or absence of a detection signal in the daytime when the brightness detected by the brightness sensor is equal to or greater than the turn-off value, there is an advantage that wasteful power consumption does not occur.
[0046]
Claim 2As in the invention of the invention, during the period from when the ambient brightness detected by the brightness sensor becomes lower than the lighting value until it becomes higher than the lighting value, excluding the holding time, the lighting control means If the light is dimmed with a light output that is less than the holding time, the dimmed light will be lit even when no person is detected during the period from when the ambient brightness falls below the lighting value to when it goes beyond the lighting value. In a place where it can function as a nightlight and it is desirable to keep it on even when there are no people, such as gate lights, stairs lights, and corridor lights, the functions of the main light and the nightlight are combined with one lighting load. There is an advantage that it becomes possible.
[0047]
Claim 3When the light output of the illumination load is used as the notice means, the light output of the illumination load is higher than the light output after expiration of the holding time and lower than before the expiration of the notice time. By changing the output, it is notified that the holding time is about to expire, so there is an advantage that it is not necessary to separately provide a notice means.
[0048]
Claim 4If an acoustically informing device is used as the notice means, it is possible to notify that the holding time is about to expire without changing the light output of the illumination load. There is an advantage that a notice can be made without changing, and there is no sense of incongruity caused by changing the brightness.
Claim 5As in the present invention, at least a heat ray sensor and a human detection means are provided, and a child device that generates a detection signal when the presence of a person is detected can be connected, a detection area is formed using a plurality of heat ray sensors. Therefore, there is an advantage that a wide detection area can be set or a detection area having a complicated shape can be set.
[Brief description of the drawings]
FIGS. 1A and 1B show a first embodiment, in which FIG. 1A is a block diagram and FIG.
FIG. 2 is a diagram showing a usage pattern of the above.
FIG. 3 is an exploded perspective view of the above.
FIG. 4 is an operation explanatory diagram of the second embodiment.
FIG. 5 is an operation explanatory view of the above.
FIG. 6 is a block diagram showing a third embodiment.
FIG. 7 is an exploded perspective view of the above.
FIG. 8 is an operation explanatory view of the above.
FIG. 9 is a block diagram showing a fourth embodiment.
FIG. 10 is a diagram showing a usage pattern of the above.
FIG. 11 is an exploded perspective view of the above.
FIG. 12 is an operation explanatory diagram of the above.
FIG. 13 is a block diagram showing a fifth embodiment.
FIG. 14 is a diagram for explaining the operation of the above.
FIG. 15 is a block diagram showing a sixth embodiment.
FIG. 16 is a diagram illustrating the operation of the above.
FIG. 17 is a block diagram illustrating a seventh embodiment.
FIG. 18 is a block diagram showing an eighth embodiment.
FIG. 19 is an operation explanatory diagram illustrating the ninth embodiment.
FIG. 20 is a block diagram illustrating a tenth embodiment.
FIG. 21 is an exploded perspective view of the above.
FIG. 22 is a diagram showing a usage pattern same as above.
[Explanation of symbols]
1 Pyroelectric sensor
2 Microcomputer
3 Brightness sensor
4 Operating illuminance adjuster
5 Lighting load
6 Buzzer
L₁  Unlit value
L₂  Lighting value
Pd dark period
Pb light period
T₁  Notice time
T₂  Holding time
X child

Claims (5)

A hot wire sensor for detecting heat rays emitted from the human body, a human detecting unit for generating a detection signal indicating the presence of a person on the basis of the preset detection area to change of the heat ray amount incident on the hot wire sensor, the ambient A brightness sensor for detecting brightness, timer means for timing a predetermined holding time and a notice time shorter than the holding time each time a detection signal is generated, and the ambient brightness detected by the brightness sensor is stipulated. turns on the period lighting load and the detection signal is generated from when a value below to a more off value bright specified from the lighting value at a predetermined optical output Rutotomoni retention time expires and detecting the light output of the lighting load is reduced to the state before the generation of a signal, that turns off the lighting load or without detection signal during the period until the following lighting value only ambient brightness or off value And control means, hot-wire automatic switch characterized in that it comprises a notifying means for warning that the expiration of the notice time during the lighting of the lighting load by the generation of the detection signal is expired retention time close. The lighting control means is a period from when the ambient brightness detected by the brightness sensor becomes equal to or lower than the lighting value until it becomes equal to or higher than the extinguishing value, and during the period excluding the holding time, the lighting load is less than the holding time. 2. The hot-wire automatic switch according to claim 1, wherein the dimming is performed with a small light output . 2. The hot wire system according to claim 1, wherein the notice means is for dimming the notice so that the light output of the illumination load is higher than the light output after the expiration of the holding time and lower than that before the expiration of the notice time. Automatic switch. 2. The hot wire automatic switch according to claim 1, wherein the notice means is an acoustic notification . Hot wire type automatic switch of claim 1 Symbol placement, wherein the slave unit for generating a detection signal upon detecting the presence with the person and at least a heat ray sensor and the man-detecting unit can be connected.

Images