JP3888286B2 - Automatic switch with hot wire sensor for remote monitoring and control system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an automatic switch with a heat ray sensor of a remote monitoring control system.
[0002]
[Prior art]
Conventionally, it has a heat ray sensor unit that detects heat rays emitted from the human body, and an automatic switch with a heat ray sensor that generates monitoring data based on the detection signal of the heat ray sensor unit, and a control that controls a load such as a lighting fixture or a ventilation fan Address data for identifying the automatic switch with a heat ray sensor and the control terminal from the transmission unit, comprising a terminal, and a transmission unit in which an automatic switch with a heat ray sensor and a control terminal are connected via a pair of signal lines By transmitting transmission signals including the signal line to the signal line by time division multiplex transmission system, the automatic switch with the hot wire sensor and the control terminal are individually accessed, and the monitoring data from the automatic switch with the hot wire sensor is received to control the operation of the load. A remote monitoring and control system is provided. In such a system, when the heat ray sensor part of the automatic switch with a heat ray sensor detects the heat ray emitted from the human body, monitoring data is generated, and the lighting device is turned on and the ventilation fan is driven in accordance with this monitoring data, and the heat ray is turned off. When a predetermined operation holding time has elapsed since the detection was stopped, the lighting fixture was turned off, and then the ventilation fan was stopped when a predetermined operation delay time had elapsed.
[0003]
Conventionally, instead of an automatic switch with a heat ray sensor, a temperature sensor unit that detects ambient temperature is provided, and a temperature sensor that generates monitoring data when the detected temperature of the temperature sensor unit becomes higher or lower than the reference temperature is provided. There is also provided a remote monitoring and control system that uses a switching device and performs operation control of a load such as an air-conditioning appliance in accordance with monitoring data from a switching device with a temperature sensor (for example, see Patent Document 1).
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 9-65454 (page 4 and FIG. 6)
[0005]
[Problems to be solved by the invention]
The automatic switch with a heat ray sensor of the remote monitoring control system described above is provided with a volume for setting the operation holding time and the operation delay time, and the time is set according to the position of the volume. Could not be set. Further, when the operation holding time and the operation delay time are set by the changeover switch, there is a problem that although the time can be set accurately, it can only be set to a predetermined value.
[0006]
On the other hand, the switch device with a temperature sensor shown in Patent Document 1 is embedded in a wall surface of a room, and a liquid crystal display for displaying a set value of a reference temperature is disposed on the front surface of the switch body. . The liquid crystal display consists of a liquid crystal panel with a touch switch, which normally displays the set value of the reference temperature. However, the screen of the liquid crystal display can be switched to the reference temperature input screen or the address data input screen. The reference temperature and address data can be input by operating the buttons displayed on the screen. With this device, the reference temperature and address data can be set while looking at the display on the liquid crystal display, so the reference temperature can be accurately set to the desired value, but the liquid crystal display is exposed to the front, so mischief and carelessness The screen of the liquid crystal display is switched to the input screen by a simple operation, and the setting value may be changed.
[0007]
The present invention has been made in view of the above-mentioned problems, and the object of the present invention is to accurately set the setting value related to the operation to a desired value, and with mischief and careless operation. An object of the present invention is to provide an automatic switch with a heat ray sensor that prevents a set value from being changed.
[0008]
[Means for Solving the Problems]
  To achieve the above object, according to the first aspect of the present invention, a plurality of terminals each having individual address data set are connected to a signal line, and transmission including address data from a transmission unit connected to the signal line is performed. Each terminal is individually accessed by sending the signal to the signal line by the time division multiplex transmission method, and the transmission unit transmits monitoring data from any terminal during the signal return period set in synchronization with the transmission signal. Upon reception, control data is created based on the monitoring data, and the control data is transmitted to the terminal device in which the correspondence relationship between the terminal device that generated the monitoring data and the address is set by the transmission signal, and the terminal device receives the control data. Control dataLighting equipment that is a loadUsed in a remote monitoring and control system that controls the operation of the sensor, a heat ray sensor unit that detects a heat ray emitted from a human body within a predetermined detection area, and a transmission signal that is connected to the signal line by a time division multiplex transmission method A transmission communication unit, a signal processing unit that outputs monitoring data for controlling a load based on a detection input of the heat ray sensor unit, a transmission control unit that transmits monitoring data output from the signal processing unit from the transmission communication unit, and each unit The switch body that is housed and the heat ray sensor part is placed on the front face, and the front face is exposed and embedded in the mounting hole provided on the ceiling surface, and the part other than the heat ray sensor part on the front face of the switch body is attached and detached A switch button for switching an item to be set to one of a plurality of setting items related to the operation of each part, and a switch to be switched by the switch button. Set value input unit to increase or decrease depending on the press operation the value of the setting item has, and the display unit is disposed at a site covered with decorative cover front switch body for displaying the value to be adjusted using the setting value input sectionThe signal processing unit turns on the luminaire at a predetermined illuminance level when the heat ray sensor unit detects a heat ray in a time other than the preset turn-off time period, and also after the heat ray sensor unit no longer detects the heat ray When the operation holding time has elapsed, the illuminance level is reduced, and the lighting is continued at the reduced illuminance level. , The lighting device is controlled to be extinguished when a predetermined operation holding time has elapsed since the heat ray sensor unit no longer detects the heat ray, and the setting items are the start time and end time of the extinguishing time zone IsIt is characterized by that.
[0009]
According to a second aspect of the present invention, in the first aspect of the present invention, the signal line is connected to a setting terminal having input means for inputting the value of the setting item, and the transmission unit is a setting terminal. When the monitor receives the monitoring data generated in response to the input operation of the input means, it creates control data for setting the value of the setting item according to the received monitoring data, and transmits the created control data using a transmission signal And a setting unit for setting the value of the setting item in accordance with control data included in the transmission signal received by the transmission communication unit.
[0010]
According to a third aspect of the present invention, in the first aspect of the invention, a wireless receiving unit that receives a setting value transmitted by a wireless signal from an external setting device, and a setting unit that sets a value of a setting item received by the wireless receiving unit It is characterized by comprising.
[0011]
  According to a fourth aspect of the present invention, in any one of the first to third aspects of the present invention,,UpThe setting item is an operation holding time.
[0012]
According to a fifth aspect of the present invention, in any one of the first to third aspects of the present invention, the setting item includes a start time of a time zone in which the signal processing unit performs a control operation according to a detection input of the heat ray sensor unit, and It is an end time.
[0014]
  Claim6According to the present invention, in any one of the first to third aspects, the setting item is a detection sensitivity of the heat ray sensor unit.
[0015]
  Claim7According to the invention, in any one of claims 1 to 3, the setting item is address data.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
  (Basic configuration1)
  Of the present inventionBasic configuration1 will be described with reference to FIGS.
[0017]
  First,heatA remote monitoring control system using an automatic switch with a line sensor will be described.
[0018]
FIG. 4 is a diagram showing the overall system configuration. The automatic switch 2 with a hot-wire sensor, the sensor on / off switch 3 and the relay control terminal 4 as terminals each having individual address data set are connected to a two-wire signal. The transmission unit 1 is connected to the signal line Ls while being connected to the line Ls. Although not shown in FIG. 4, a plurality of relay control terminals 4 are connected to the signal line Ls, and a plurality of lighting fixtures 5 and ventilation fans 6 are turned on / off by the automatic switch 2 with a heat ray sensor. Control off.
[0019]
The transmission unit 1 accesses each terminal individually by sending a transmission signal including address data to the signal line Ls by a time division multiplex transmission method, and any one of the signal reply periods set in synchronization with the transmission signal. When monitoring data is received from the terminal device, control data is created based on the monitoring data, and the control data is transmitted by a transmission signal to the terminal device for which the correspondence between the terminal device that generated the monitoring data and the address is set. In the terminal, the operation of the load is controlled by the received control data.
[0020]
The automatic switch 2 with a heat ray sensor includes a heat ray sensor (not shown) that detects the presence or absence of a person in the detection area by detecting a heat ray emitted from a human body in a predetermined detection area. The automatic switch 2 with a heat ray sensor is connected to a heat ray sensor unit 2 'having a heat ray sensor for detecting a heat ray emitted from a human body in different detection areas. When the output of 2 'is monitored and any one of them detects a hot wire, an interrupt signal is generated and monitoring data is sent to the transmission unit 1.
[0021]
The sensor on / off switch 3 includes a switch SW1 for turning on / off the control operation of the lighting fixture 5 and the ventilation fan 6 by the automatic switch 2 with a heat ray sensor, and an on state and a off state of a control operation by the automatic switch 2 with a heat ray sensor. Are provided with indicator lights LDa and LDb such as light emitting diodes, respectively, and monitor data is transmitted to the transmission unit 1 in response to the pressing operation of the switch SW1.
[0022]
The relay control terminal 4 includes a relay (not shown) for turning on / off the power supply to the lighting device 5 and the ventilation fan 6 as loads, and turns on / off the corresponding relay according to the received control data. Then, the lighting fixture 5 is turned on or off, and the ventilation fan 6 is driven or stopped. In general, a latching type relay is used, and the relay control terminal 4 supplies power to the relay in pulses when the relay is operated.
[0023]
Next, the operation of the remote monitoring control system will be briefly described. For the sake of simplicity, the automatic switch 2 with a heat ray sensor and the sensor on / off switch 3 are collectively referred to as a monitoring terminal.
[0024]
The transmission unit 1 sends the transmission signal Vs having the format shown in FIG. 5A to the signal line Ls. That is, the transmission signal Vs includes the synchronization signal SY indicating the start of signal transmission, the mode data MD indicating the mode of the transmission signal Vs, and the addresses (8 of the terminal devices for monitoring (the monitoring terminals 2 and 3 and the relay control terminal device 4)). Address data AD indicating bits), control data CD indicating control contents, checksum data CS for detecting a transmission error, and a signal which is a time slot provided for returning a return signal (monitoring data) from the terminal This is a bipolar (± 24V) time-division multiplexed signal consisting of a return period WT, and data is transmitted by pulse width modulation (see FIG. 5B).
[0025]
In the monitoring terminals 2 and 3 and the relay control terminal 4, basically, when the address data AD of the transmission signal Vs received via the signal line Ls matches the preset address data of itself. The control data CD of the transmission signal Vs is fetched and the monitoring data is sent out by short-circuiting the signal line Ls via an appropriate low impedance in synchronization with the signal return period WT of the transmission signal Vs. Signal) to the transmission unit 1.
[0026]
Here, when data is transmitted from the transmission unit 1 to the desired terminals 2, 3, and 4, the mode data MD is set to the control mode, and the address data AD is set to the addresses of the desired terminals 2, 3, and 4. If the transmission signal Vs is sent to the signal line Ls, the terminals 2, 3 and 4 having the matching address data AD receive the control data CD and return monitoring data during the signal return period WT. The transmission unit 1 confirms that the control data CD has been transmitted to the desired terminals 2, 3 and 4 based on the transmitted control data CD and the monitoring data received during the signal return period WT. The relay control terminal 4 instructs the operation of the relay according to the received control data CD, and the sensor on / off switch 3 performs operations such as turning on or off the indicator lamp 3b according to the received control data CD.
[0027]
On the other hand, the transmission unit 1 normally sends a transmission signal Vs in which the mode data MD is set to the dummy mode at regular time intervals (always polling), and the monitoring terminals 2 and 3 monitor input (detection input of the heat ray sensor, When any information is to be transmitted to the transmission unit 1 in response to the operation input of the switch, the interrupt signal Vi as shown in FIG. 5C is synchronized with the synchronization signal ST of the transmission signal Vs in the dummy mode. generate.
[0028]
At this time, the monitoring terminals 2 and 3 set an interrupt flag to prepare for subsequent information exchange with the transmission unit 1. When the transmission unit 1 receives the interrupt signal Vi, the mode data MD is set to the interrupt polling mode and the upper half of the address data AD (the upper 4 bits if the address data AD is 8 bits) is sequentially increased. In the monitoring terminals 2 and 3 that transmit the transmission signal and generate the interrupt signal Vi, when the upper 4 bits of the address data AD in the transmission signal Vs in the interrupt polling mode match the upper 4 bits of its own address During the signal return period WT, the lower half bits (lower 4 bits) of its own address are returned to the transmission unit 1 as monitoring data. In this way, the transmission unit 1 searches for 16 monitoring terminals 2 and 3 that have generated the interrupt signal Vi one by one, so that the monitoring terminals 2 and 3 can be found in a relatively short time.
[0029]
When the transmission unit 1 acquires the address of the monitoring terminals 2 and 3 that generated the interrupt signal Vi, the mode data MD is set to the monitoring mode, and the transmission signal Vs having the acquired address data AD is sent to the signal line Ls. In response to this transmission signal, the monitoring terminals 2 and 3 return information to be transmitted in the signal return period WT. Finally, the transmission unit 1 sends a signal instructing the reset of the interrupt flag to the monitoring terminals 2 and 3 that have generated the interrupt signal, and cancels the interrupt flag of the monitoring terminals 2 and 3. .
[0030]
As described above, information transmission from the monitoring terminals 2 and 3 to the transmission unit 1 is performed four times from the transmission unit 1 to the monitoring terminals 2 and 3 (dummy mode, interrupt polling mode, Completed by monitoring mode, interrupt reset). Further, when the transmission unit 1 wants to know the operation state of the desired relay control terminal 4, it transmits a transmission signal Vs with the mode data MD as monitoring data and the address data AD as the address of the desired relay control terminal 4. The monitoring data from the desired relay control terminal 4 can be acquired during the signal return period WT of the transmission signal Vs.
[0031]
Here, when the heat ray sensor part of the automatic switch 2 with a heat ray sensor detects a heat ray emitted from the human body and generates a detection signal, or when the switch SW1 of the sensor on / off switch 3 is operated to generate an operation signal, The automatic switch 2 with a hot wire sensor or the switch 3 for turning on and off the sensor generates an interrupt signal Vi, and after passing through the above-described transmission procedure, transmits the monitoring data corresponding to the detection signal of the hot wire sensor unit or the operation signal of the switch SW1. Return to Then, when the transmission unit 1 creates the control data CD based on the monitoring data received from the monitoring terminals 2 and 3, and transmits the created control data CD to the corresponding terminal, the control data CD is received. The terminal performs a predetermined operation. For example, when monitoring data corresponding to the detection input of the heat ray sensor is returned from the automatic switch 2 with a heat ray sensor, the transmission unit 1 transmits control data created based on this monitoring data to the relay control terminal 4. When the relay control terminal 4 receives the control data, the relay control terminal 4 controls the relay to turn on / off the lighting fixture 5 and turn on / off the ventilation fan 6. When the monitoring data corresponding to the ON / OFF operation of the switch SW1 is returned from the sensor on / off switch 3, the transmission unit 1 transmits the control data created based on the monitoring data to the automatic switch 2 with a heat ray sensor. When receiving the control data, the automatic switch with heat ray sensor 2 turns on / off the load control operation based on the detection input of the heat ray sensor. Moreover, the automatic switch 2 with a heat ray sensor returns monitoring data indicating ON / OFF of the control operation to the transmission unit 1, and the transmission unit 1 switches to the sensor ON / OFF switch 3 based on this monitoring data. Control data for turning on / off the attached operation monitor indicator lights LD3, LD4 is transmitted, and the sensor on / off switch 3 that has received the control data receives a corresponding operation monitor based on the control data. The on / off state of the control operation by the automatic switch 2 with a heat ray sensor is displayed by turning on or off the display lamps LDa and LDb.
[0032]
As described above, in this system, data is exchanged between the terminals using the correspondence relationship of addresses set in advance in the transmission unit 1, so that the monitoring input of any of the monitoring terminals 2 and 3 can be made. In response, the operation of the corresponding terminal is controlled.
[0033]
Next, the circuit configuration of the automatic switch 2 with a heat ray sensor will be described with reference to FIG.
[0034]
As shown in the block diagram of FIG. 3, the automatic switch 2 with a heat ray sensor includes a CPU 10, a heat ray sensor detection circuit 11, a heat ray sensor slave signal circuit 12, a brightness detection circuit 13, and a multiplex transmission signal transmission / reception circuit 14. And a power supply circuit 15, a liquid crystal display circuit 16, an operation input circuit 17, and a nonvolatile memory 18.
[0035]
The heat ray sensor detection circuit 11 includes a heat ray sensor unit (not shown) such as a pyroelectric element that detects heat rays emitted from the human body, amplifies the output of the heat ray sensor unit, and outputs the amplified output to the CPU 10. The CPU 10 determines the presence or absence of a person in the detection area by comparing the output of the heat ray sensor detection circuit 11 with a predetermined threshold value stored in the nonvolatile memory 18.
[0036]
The hot wire sensor slave signal circuit 12 is connected to the hot wire sensor slave device 2 'via a pair of terminals T2, and full-wave rectifies the transmission signal Vs input via the signal line Ls to make the voltage constant. As a result, an operating power supply for the heat ray sensor sub-unit 2 ′ is generated and supplied to the heat ray sensor sub-unit 2 ′, and the voltage between the terminals T2 and T2 is monitored to output the heat ray sensor sub-unit 2 ′. Is monitoring. That is, the hot-wire sensor sub-unit 2 ′ includes a hot-wire sensor (not shown) such as a pyroelectric element that detects a heat ray radiated from the human body, and when the heat-wire sensor detects a heat ray from the human body, the terminal T2, By lowering the voltage level during T2 as compared with the non-detection time, the fact that the heat ray has been detected is notified to the heat ray sensor slave unit signal circuit 12. Thus, when the heat ray sensor slave unit signal circuit 12 determines that the heat ray sensor slave unit 2 'has detected a heat ray from the voltage between the terminals T2 and T2, it outputs a detection signal to the CPU 10 via the heat ray sensor detection circuit 11. To do.
[0037]
The brightness detection circuit 13 includes brightness sensors (not shown) such as CdS, photodiodes, and phototransistors that detect ambient brightness, and amplifies the output of the brightness sensor and outputs the amplified output to the CPU 10. The CPU 10 compares the brightness of the output of the brightness detection circuit 13 with the predetermined brightness level (set level) stored in the nonvolatile memory 18.
[0038]
The multiplex transmission signal transmission / reception circuit 14 serving as a transmission communication unit performs transmission / reception of transmission signals by the multiplex transmission method with the transmission unit 1 via the signal line Ls connected to the pair of terminals T1, T1. The transmission signal input via the signal line Ls is converted into a signal and output to the CPU 10, and the signal output from the CPU 10 is converted into a transmission signal and sent to the signal line Ls.
[0039]
The power supply circuit 15 performs full-wave rectification on the transmission signal Vs input via the signal line Ls by a full-wave rectifier (not shown), and further converts the transmission signal Vs to a constant voltage by a constant voltage circuit (not shown). Getting circuit power.
[0040]
The operation input circuit 17 is for inputting values of various setting items (for example, address data) related to the operation of the switch and for checking the setting values.
[0041]
The liquid crystal display circuit 16 displays the setting items and their values input using the operation input circuit 17 on the liquid crystal display unit 16a serving as a display unit.
[0042]
The nonvolatile memory 18 is composed of, for example, an EEPROM, and stores values of setting items (for example, address data and operation holding time) input by the operation input circuit 17.
[0043]
Further, when the address data included in the transmission signal received via the multiplex transmission signal transmission / reception circuit 14 matches the address data stored in the nonvolatile memory 18, the CPU 10 receives the control data of the transmission signal and responds to the control data according to the control data. To work. The fact that the transmission signal has been received is sent from the terminals T1 and T1 to the signal line Ls through the multiplex transmission signal transmission / reception circuit 14.
[0044]
Here, operation | movement of the automatic switch 2 with a heat ray sensor is demonstrated based on FIG. When an operation for turning off the control operation of the automatic switch 2 with a heat ray sensor is performed using the switch SW1 of the sensor on / off switch 3, the sensor on / off switch 3 sends out an interrupt signal, and after passing through the above transmission processing. The on / off address set in the automatic switch 2 with a hot wire sensor is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data for turning off the control operation to the automatic switch 2 with the heat ray sensor based on the return signal received from the sensor on / off switch 3, and the automatic switch with the heat ray sensor that has received this control data. 2 turns off the control action.
[0045]
On the other hand, when an operation to turn on the control operation of the automatic switch 2 with a heat ray sensor is performed using the switch SW1 of the sensor on / off switch 3, the same operation as described above is performed, and the control operation of the automatic switch 2 with a heat ray sensor is performed. Set to the on state. When the control operation is set to the on state, the automatic switch 2 with a heat ray sensor controls the load based on the outputs of the heat ray sensor detection circuit 11 and the heat ray sensor slave signal circuit 12 and the brightness detection circuit 13. . In a state where the brightness detected by the brightness sensor is brighter than a predetermined brightness level, the CPU 10 has an input from the heat ray sensor detection circuit 11 exceeding a threshold value or a detection input from the heat ray sensor slave signal circuit 12. Even if it exists, the control operation is not performed. On the other hand, the CPU 10 is in a state where the brightness detected by the brightness sensor is darker than a predetermined brightness level, the input from the heat ray sensor detection circuit 11 exceeds the threshold value, or the heat ray sensor slave unit signal circuit 12 sends a heat ray. When there is a detection input through the sensor detection circuit 11, an interrupt signal is transmitted from the multiplex transmission signal transmission / reception circuit 14, and after passing through the above-described transmission procedure, ON address data (for example, pattern control pattern P1) is used as a return signal. The transmission unit 1 is returned. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1. Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and returns the data (P2) of the OFF address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and thins the lighting fixture 5 in the illumination range set by the pattern P2. (See FIG. 6 (c)).
[0046]
When delaying a load such as a ventilating fan, the CPU 10 sends out an interrupt signal from the multiplex transmission signal transmitting / receiving circuit 14 at the time of detection input, and relays for controlling the load after the above transmission procedure. The address of the control terminal 4 (referred to as a delay address) is sent back to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data for turning on the load to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and operates (ON) the load. The CPU 10 sends out an interrupt signal from the multiplex transmission signal transmitting / receiving circuit 14 when a predetermined operation holding time elapses after the detection input disappears and then a predetermined operation delay time elapses, and the above transmission procedure is performed. Later, the data of the delay address is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data for turning off the load to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and stops (OFF) the corresponding load (FIG. 6 (d)). Here, the signal processing unit that outputs the monitoring data for controlling the load based on the detection input of the heat ray sensor unit, and the transmission control unit that transmits the monitoring data output from the signal processing unit from the transmission communication unit are the calculation functions of the CPU 10 It is realized by.
[0047]
Next, the structure of the automatic switch 2 with a heat ray sensor will be described with reference to FIGS. The automatic switch 2 with a heat ray sensor is a disc-shaped flange in which a window hole 22a is formed in the center and a pair of holding grooves 22b are formed on both sides so that the automatic switch 2 is embedded in a mounting hole provided in the ceiling. In addition to a body 21 including a portion 22 and a cylindrical portion 23 integrally formed at the center of the upper surface and having four engagement protrusions 23a each having an engagement hole 23b extending on the upper edge, A cover 24 that is attached to the cylindrical portion 23, a plate 25 that is attached to the front surface of the body 21 (the lower surface in FIG. 1B), a pair of clamps 26, a rotating body 27, and a support member. 28, a printed circuit board 29, and a flat terminal cover 30.
[0048]
The clamp 26 has a vertically long box-like column 31 having a pair of engaging protrusions 31a that engage with a pair of holding grooves 22b at the lower end and open to one end, and upper and lower ends on the upper and bottom walls, respectively. The tightening screw 32 is inserted into the support column 31 and is rotatably held. The clamping screw 33 is engaged with the tightening screw 32. The pinch piece 33 is moved from the notch 31 b provided on the side wall of the column 31 by rotating the tightening screw 32 and is lowered along the opening surface of the column 31. Accordingly, the pair of engaging protrusions 31a of each clip metal fitting 26 are respectively engaged with the pair of holding grooves 22b of the flange portion 22, and each clip metal fitting 26 is detachably attached to the body 21, and then each clip metal fitting 26 and After inserting the cylindrical portion 23 into a mounting hole (not shown) formed in the ceiling board, if the clamping piece 33 is lowered by turning the tightening screw, the clamping piece is respectively placed on the upper and lower surfaces of the board in the vicinity of the peripheral portion of the mounting hole. The lower surface of the distal end portion 33 and the upper surface of the flange portion 22 come into contact (pressure contact), and the body 21 is attached to the ceiling.
[0049]
The plate 25 has a round hole 25a corresponding to the window hole 22a in the center portion, is held by being engaged with the flange portion 22, and functions as a decorative cover.
[0050]
The rotating body 27 includes a hemispherical rotating frame 34 having shaft portions 34a projecting from both ends, and a lens (for example, a multifocal lens formed of a Fresnel lens) that is coupled to the front side (lower side in the figure) to become a window portion. Lens) 35, a heat ray sensor unit and a brightness sensor are mounted on the lower surface, the rotating frame 34 and the detection system printed circuit board 36 housed in the lens 35, and the rotating frame 34 and the lens 35 are attached to the coupling portion of the rotating frame. 34 and the ring-shaped holding frame 37 fitted to each other.
[0051]
The support member 28 includes a presser fitting 38, a support bar 40 attached to the presser fitting 38 via a spring 39, and two screws 41. The support member 28 is for fixing the rotating body 27 to the body 21 in a freely rotatable manner. It is. That is, each shaft portion 34a of the rotating frame 34 is inserted into a guide groove 22c extending upward from the lower end side formed in the peripheral portion of the window hole 22a, and then supported by the two screws 41 through the spring 39. If the presser fitting 38 to which the rod 40 is attached is screwed to the body 21, the upper portion of the rotating body 27 is elastically pressed against the support rod 40, and the rotating body 27 is rotatably fixed to the body 21. become.
[0052]
The above-described circuit is formed on the printed circuit board 29, and is electrically connected to the detection system printed circuit board 36 via a plurality of (three in the figure) lead wires W1, and is screwed onto the body 21 by two screws 42. Stopped.
[0053]
The cover 24 is formed in a box shape that closes the opening of the cylindrical portion 23, and an engagement protrusion 24 a that engages with the engagement hole 23 b of each engagement protrusion 23 a is formed on the side wall portion. On the other hand, a pair of terminals T1 to which the signal line Ls is connected and a pair of terminals T2 for connecting the heat ray sensor slave unit 2 ′ are provided on the upper surface. These terminals T1, T2 are connected to the printed circuit board 29 via lead wires W2.
[0054]
The printed circuit board 29 is screwed to the body 21 so that the printed circuit board 29 is positioned on the rotating body 27 that is fixed to the body 21 so as to be freely rotatable, and each of the engagement protrusions 24a is connected to the corresponding engagement protrusion 24a. When engaged with the engagement hole 23 b of the piece 23 a, the opening of the cylindrical portion 23 is closed by the cover 24, and the printed circuit board 29 is accommodated by the body 21 and the cover 24. Here, the body 21 and the cover 24 constitute a switch body embedded in a mounting hole provided in the ceiling surface with the front surface exposed.
[0055]
In addition, the heat ray sensor unit is mounted on the detection system printed circuit board 36, so that the multifocal lens 35 is positioned in front of the heat ray sensor unit, resulting in uneven sensitivity in the field of view. If the person moves minutely within this, the heat dose incident on the light receiving surface of the heat ray sensor section is likely to change, so that the detection capability of the person's minute movement is improved and the presence / absence of the person in the surroundings can be determined.
[0056]
Also, on the lower surface of the printed circuit board 29 (the surface facing the flange portion 22), a liquid crystal display portion 16a whose display is controlled by the liquid crystal display circuit 16 and four switches such as a tact switch are mounted. The operation buttons 17a to 17d of the switches and the liquid crystal display portion 16a are exposed to the front side of the body 21 through window holes 22d and 22e provided in the flange portion 22.
[0057]
  As mentioned aboveThis automatic switch with heat ray sensorThen, an operation input circuit 17 for increasing / decreasing a value of a desired setting item in accordance with the pressing operation of the operation buttons 17a to 17d as the operation input unit, and a setting item and its input value input by the operation input circuit 17 are displayed on the liquid crystal display unit. Since the liquid crystal display circuit 16 to be displayed on 16a is provided, the values of various setting items can be set by operating the operation buttons 17a to 17d while viewing the display on the liquid crystal display unit 16a. The operation button 17a is a button for performing a determination operation, the operation button 17b is an ESC button for performing a cancel operation, and the operation buttons 17c and 17d function as setting item switching buttons when a setting item is selected. When inputting a value, the operation button 17c functions as a button for increasing the value of the setting item, and the operation button 17d functions as a button for decreasing the value of the setting item. On the front surface (lower surface) of the body 21, characters (“ENT” and “ESC”) and symbols (“▲” and “▼”) indicating the function of each button are provided in the vicinity of the operation buttons 17a to 17d. It is displayed.
[0058]
  This switchThen, as setting items to be set using the operation buttons 17a to 17d, an address (ON address) to be controlled at the time of detection by the heat ray sensor unit and an address (OFF address) to be controlled after a predetermined operation holding time has elapsed since the detection was lost. Address), the address (on / off address) specified when turning on / off the control operation according to the detection input of the heat ray sensor unit, the address of the terminal device (delay address) performing delay control, and the operation state after detection For holding the operation (operation holding time), the time for further delaying the operation from the time when the operation holding time has passed (operation delay time), and the brightness that serves as a reference for enabling or disabling the detection input of the heat ray sensor unit The level can be adjusted. It should be noted that self address data may be provided as a setting item so that the value of the address data can be set with a switch, and a separate address setting tool is not required.
[0059]
7A to 7G show display examples of the liquid crystal display unit 16a. The contents of the setting items are displayed on the upper side of the screen, and the values are displayed on the lower side of the screen. The operation buttons 17c, By pressing 17d, the display of the display items is switched in a predetermined order, and the setting value of each setting item can be confirmed. 7A is an ON address display screen, FIG. 7B is an OFF address display screen, FIG. 7C is an on / off address display screen, and FIG. 7D is a delay address display screen. 7E is an operation holding time display screen, FIG. 7F is an operation delay time display screen, and FIG. 7G is a brightness level display screen.
[0060]
Here, the procedure for setting “P5” to the OFF address will be described with reference to FIGS. Normally, the power supply to the liquid crystal display unit 16a is stopped. For example, when any one of the operation buttons 17a to 17d is pressed, the power supply to the liquid crystal display unit 16a is started, as shown in FIG. An initial screen as shown is displayed. In the initial state, the set value of the ON address is displayed on the liquid crystal display unit 16a. When the operation button 17c or 17d is pressed in this state, the setting items displayed on the liquid crystal display unit 16a are switched. When a desired setting item (in this case, an OFF address) is displayed as shown in FIG. 8B, the setting item to be adjusted is determined by pressing the operation button 17a, and setting value adjustment work is started. The The OFF address is composed of a type of control content such as pattern control, group control, individual control, and dimming control and a channel number, and is first switched to an input screen for inputting the type of control content (see FIG. 8C). In the screen of FIG. 8C, the control type is pattern control (P). When the operation button 17c is pressed once on this screen, the control type is set to group control (G), and when pressed again, the control type is set to individual control. If the operation button 17a is pressed when the control type is switched to the desired control type when the button is pressed once more, the control type is determined and the screen is switched to a screen for inputting a number (see FIG. 8D). ). In the screen of FIG. 8D, the number is “2”, the number increases by one each time the operation button 17c is pressed, and the number decreases by one each time the operation button 17d is pressed. Become. Then, as shown in FIG. 8E, when the number reaches a desired value, when the operation button 17a is pressed and a determination operation is performed, the value of the OFF address is fixed and a setting value is displayed (FIG. 8). 8 (f)). If a cancel operation is performed by pressing the operation button 17b during the adjustment, the setting contents are not changed and the initial screen of the item is returned.
[0061]
Next, the procedure for setting the operation holding time to “10 sec” will be described with reference to FIGS. As shown in FIG. 9A, in the initial state, the set value of the ON address is displayed on the liquid crystal display unit 16a. When the determination operation is performed by pressing the operation button 17c or 17d in this state, the liquid crystal display unit The setting item displayed in 16a is switched. As shown in FIG. 9B, when a desired setting item (in this case, the operation holding time) is displayed, the setting item to be adjusted is determined by pressing the operation button 17a, and the adjustment operation of the operation holding time is started. Is done. First, the screen is switched to an input screen for inputting the value of the operation holding time (see FIG. 9C). Each time the operation button 17c is pressed on this screen, the value of the operation holding time increases by one, and the operation button 17d is pressed. Each time it is pressed, the value of the operation holding time is decreased by one. As shown in FIG. 9D, when the operation holding time value is switched to the desired value “10”, when the operation button 17a is pressed, the operation holding time value is determined, and the screen is switched to a screen for inputting a unit of time. (See FIG. 9 (e)). In the screen of FIG. 9E, the unit is “min” (minutes). When the operation button 17c is pressed once, the unit is “hour” (hours), and when the button is pressed again, “sec” (seconds). Therefore, when the operation button 17a is pressed and a determination operation is performed when the unit is switched to a desired unit, the set value of the operation holding time is fixed and the set value is displayed (see FIG. 9G). Switch to If a cancel operation is performed by pressing the operation button 17b during the adjustment, the setting content is not changed, and the screen returns to the initial screen for that item. Since the input method other than the OFF address and the operation holding time is the same as described above, the description thereof is omitted.
[0062]
As described above, when the setting item to be input is switched or the value is input according to the input operation of the operation buttons 17a to 17c, the CPU 10 controls the liquid crystal display circuit 16 to set the setting item in the liquid crystal display unit 16a. Therefore, the setting operation can be performed while viewing the display on the liquid crystal display unit 16a, and the value of the desired setting item can be set accurately.
[0063]
  Conventionally, in order to set the address data to the automatic switch with a heat ray sensor, a wireless setting device that transmits the address data with a wireless signal such as infrared rays is used, and the infrared light emitting part of the wireless setting device is automatically set with a heat ray sensor. By performing infrared communication close to the infrared light receiving part of the switch, address data was set in the automatic switch with a heat ray sensor. However, if the infrared light emitting part and the infrared light receiving part are misaligned, the infrared communication fails. There is a problem that it is difficult to perform the setting work because it must be set again and again. On the other hand, bookswitchThen, since the setting operation is performed using the operation buttons 17a to 17d provided on the switch body, the setting operation can be performed reliably, and there is no need to separately prepare a wireless setting device.
[0064]
  by the way,This switchThen, as shown in FIG. 6C, the lighting fixture 5 is thinned and lit even after the ambient brightness detected by the brightness sensor becomes brighter than a predetermined brightness level. As shown in d), all the lighting fixtures 5 may be turned off when the surrounding brightness becomes brighter than a predetermined brightness level, and unnecessary lighting may be turned off when the surrounding becomes bright. it can. In this case, as shown in FIG. 11, in addition to the above items as setting items, an address (stop address) that is controlled when the brightness level becomes brighter than the set level is provided. What is necessary is just to set the pattern P3 which makes the instrument 5 light-extinguish.
[0065]
The operation in this case will be briefly described with reference to FIG. When the control operation of the automatic switch 2 with the heat ray sensor is set to the ON state using the switch SW1 of the sensor ON / OFF switch 3, the automatic switch 2 with the heat ray sensor includes the heat ray sensor detection circuit 11 and the heat ray sensor slave unit signal circuit. The load is controlled based on the output of 12 and the output of the brightness detection circuit 13. The CPU 10 is in a state where the brightness detected by the brightness sensor is darker than a predetermined brightness level, and the input from the heat ray sensor detection circuit 11 exceeds the threshold value or the heat ray sensor detection signal from the heat ray sensor slave signal circuit 12 is detected. When there is a detection input through the circuit 11, the multiplex transmission signal transmission / reception circuit 14 sends out an interrupt signal, and after passing through the above-described transmission procedure, the ON address data (P1) is sent back to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1. Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and returns the data (P2) of the OFF address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and thins the lighting fixture 5 in the illumination range set by the pattern P2. . When the brightness detected by the brightness sensor becomes brighter than a predetermined brightness level, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and after passing through the above transmission procedure, stops address data (P3). ) Is returned to the transmission unit 1 as a return signal, and the transmission unit 1 receiving this monitoring data sends control data to the corresponding relay control terminal 4 and turns off all the lighting fixtures 5 set in the pattern P3. (See FIG. 10C).
[0066]
  still,This switchThen, when the specified operation holding time has elapsed from the detection input, the entire illumination level is reduced by switching from full lighting to thinning lighting, but switching from full lighting to dimming lighting when the operation holding time has elapsed. Thus, the illuminance level of each lighting fixture may be lowered.
[0067]
  (Basic configuration2)
  Of the present inventionBasic configuration2 will be described with reference to FIGS.
[0068]
  Described in Basic Configuration 1In the automatic switch with a heat ray sensor, the CPU 10 compares the ambient illuminance detected by the brightness detection circuit 13 with a predetermined brightness level (set level), and the ambient illuminance is darker than the brightness level. Only when the output of the heat ray sensor detection circuit 11 and the heat ray sensor slave unit signal circuit 12 is valid,This switchIs provided with a timer circuit 19 for counting the current time. If the current time counted by the timer circuit 19 is between the start time and the end time stored in the nonvolatile memory 18, the heat ray sensor detection circuit 11 or the heat ray sensor is provided. A control operation is performed in accordance with the output of the slave unit signal circuit 12. Other than the timer circuit 19,Switch described in Basic Configuration 1Therefore, the illustration and description of the configuration and operation are omitted.
[0069]
The operation of the automatic switch 2 with a heat ray sensor will be described with reference to FIG. When the control operation of the automatic switch with heat ray sensor 2 is set to the OFF state by using the switch SW1 of the sensor on / off switch 3, the automatic switch with heat ray sensor 2 does not perform the load control operation.
[0070]
  On the other hand, when the control operation of the automatic switch with heat ray sensor 2 is set to the ON state using the switch SW1 of the switch for turning on and off the sensor 3, the automatic switch with heat ray sensor 2 includes the heat ray sensor detection circuit 11 and the heat ray sensor element. The load is controlled based on the output of the signal generator circuit 12 and the current time counted by the timer circuit 19. If the current time counted by the timer circuit 19 is before the start time or after the end time, the CPU 10 determines whether the input from the heat ray sensor detection circuit 11 exceeds the threshold value or the detection input from the heat ray sensor slave signal circuit 12 is received. Even if it exists, the control operation is not performed. On the other hand, if the current time counted by the timer circuit 19 is between the start time and the end time, the CPU 10 detects whether the input from the heat ray sensor detection circuit 11 exceeds the threshold value or from the heat ray sensor slave signal circuit 12. When there is an input, the multiplex transmission signal transmission / reception circuit 14 sends out an interrupt signal, and after passing through the above transmission procedure, the data (P1) of the ON address is sent back to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1. Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and returns the data (P2) of the OFF address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and thins the lighting fixture 5 in the illumination range set by the pattern P2. (See FIG. 13 (c)). In addition, the operation when delaying the load such as a ventilation fan isSwitch described in Basic Configuration 1Since this is the same, the description thereof is omitted.
[0071]
  Switch described in Basic Configuration 1If the control operation according to the detection input from the heat ray sensor detection circuit 11 or the heat ray sensor slave signal circuit 12 is performed when the ambient illuminance is darker than the reference brightness level, the detection of the heat ray sensor unit is performed. In a case where people frequently pass through the area, the number of times the lighting fixture 5 is turned on / off increases, resulting in a problem that the life of the relay and the lighting fixture 5 is shortened. Therefore,This switchThe control operation is performed based on the outputs of the heat ray sensor detection circuit 11 and the heat ray sensor slave signal circuit 12 in a preset time zone, and the time zone in which people frequently pass through the detection area is controlled by the heat ray sensor unit. If the operation is stopped and the lighting fixture 5 is forcibly lit, the number of times the lighting fixture 5 is turned on / off can be reduced, and the life of the relay and the lighting fixture 5 can be extended.
[0072]
  here,This switchAlso inSwitch described in Basic Configuration 1It is possible to adjust the value of the setting item related to the operation in the same way as the ON item, the OFF address, the ON / OFF address, the delay address, the operation holding time, the operation delay time, and the hot wire sensor. It is possible to adjust the start time (hereinafter referred to as operation time) and end time (hereinafter referred to as stop time) of the time zone in which the control operation corresponding to the detection input is performed, and the current time. 14A to 14I show examples of display on the liquid crystal display unit 16a. The contents of the setting items are displayed on the upper side of the screen, and the values thereof are displayed on the lower side of the screen. The operation buttons 17c, By pressing 17d, the display of the display items is switched in a predetermined order, and the setting value of each setting item can be confirmed. 14A is an ON address display screen, FIG. 14B is an OFF address display screen, FIG. 14C is an on / off address display screen, and FIG. 14D is a delay address display screen. 14 (e) is an operation holding time display screen, FIG. 14 (f) is an operation delay time display screen, FIG. 14 (g) is an operation time display screen, and FIG. 14 (h) is a stop time display screen. FIG. 14 (i) is a display screen of the current time. The procedure to set the value of each setting item isSwitch described in Basic Configuration 1Since this is the same, the description thereof is omitted.
[0073]
  by the way,This switchThen, as shown in FIG. 13C, when the luminaire 5 is turned on in response to the detection input, the luminaire 5 is turned on even after the stop time, but FIGS. 15A to 15D. ) When the stop time comes, all the lighting fixtures 5 may be turned off, and unnecessary illumination can be turned off. In this case, as shown in FIG. 16, in addition to the above items as setting items, an address (stop address) to be controlled when the stop time comes is provided, and a pattern for turning off all the luminaires 5 at this stop address P3 may be set.
[0074]
The operation in this case will be briefly described with reference to FIG. When the control operation of the automatic switch 2 with the heat ray sensor is set to the ON state using the switch SW1 of the sensor ON / OFF switch 3, the automatic switch 2 with the heat ray sensor includes the heat ray sensor detection circuit 11 and the heat ray sensor slave unit signal circuit. 12 and the output of the timer circuit 19 are used to control the load. If the current time counted by the timer circuit 19 is between the start time and the end time, the CPU 10 has an output from the heat ray sensor detection circuit 11 that exceeds a threshold value or a detection input from the heat ray sensor slave signal circuit 12. An interrupt signal is transmitted from the multiplex transmission signal transmission / reception circuit 14, and after passing through the above-described transmission procedure, the data (P1) of the ON address is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1. Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and returns the data (P2) of the OFF address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and thins the lighting fixture 5 in the illumination range set by the pattern P2. . When the current time counted by the timer circuit 19 becomes the stop time, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmitting / receiving circuit 14, and after passing through the above-described transmission procedure, the stop address data (P3) is used as a return signal. The transmission unit 1 is returned to the transmission unit 1 and receives the monitoring data. The transmission unit 1 sends the control data to the corresponding relay control terminal 4 and turns off all the luminaires 5 set in the pattern P3 (FIG. 15 ( c)).
[0075]
  still,This switchThen, when the specified operation holding time has elapsed from the detection input, the entire illumination level is reduced by switching from full lighting to thinning lighting, but switching from full lighting to dimming lighting when the operation holding time has elapsed. Thus, the illuminance level of each lighting fixture may be lowered.
[0076]
  (Embodiment1)
  Embodiment of the present invention1Will be described with reference to FIGS.
[0077]
  FIG. 17 is a block diagram of the present embodiment.Explain in basic configurationA timer circuit 19 for counting the current time is provided in the automatic switch with a heat ray sensor.Basic configuration 1 switchThen, when there is a detection input, the plurality of lighting fixtures 5 are all turned on, and when a predetermined operation holding time has elapsed from the detection input, the lighting fixtures 5 in a predetermined illumination range are lit out or adjusted. In contrast to the light being turned on, in the present embodiment, if there is a detection input from when the ambient brightness becomes darker than the set level until the turn-off time stored in the nonvolatile memory 18 comes, the lighting fixture 5 Are turned on, and when the operation holding time has elapsed from the detection input, the thinning lighting and the dimming lighting are performed, and when the turn-off time (for example, 23:00) stored in the nonvolatile memory 18 comes after that, When the operation holding time has passed, the lighting fixture 5 is turned off. After that, when the recovery time (for example, 06:00) stored in the nonvolatile memory 18 comes, the operation holding time is detected from the detection input. So that thinned out lighting and dimming lighting at the time spent. Other than the timer circuit 19,Switch described in Basic Configuration 1Therefore, the illustration and description of the configuration and operation are omitted.
[0078]
The operation of the automatic switch 2 with a heat ray sensor will be described with reference to FIG. When the control operation of the automatic switch with heat ray sensor 2 is set to the OFF state by using the switch SW1 of the sensor on / off switch 3, the automatic switch with heat ray sensor 2 does not perform the load control operation.
[0079]
On the other hand, when the control operation of the automatic switch 2 with a heat ray sensor is set to the ON state using the switch SW1 of the switch 3 for turning on and off the sensor, the automatic switch 2 with a heat ray sensor includes the heat ray sensor detection circuit 11, the heat ray sensor slave unit. The load is controlled based on the outputs of the signal circuit 12, the brightness sensor detection circuit 13, and the timer circuit 19. In a state where the brightness detected by the brightness sensor is brighter than a predetermined brightness level, the CPU 10 does not perform the control operation even if there is a detection input from the heat ray sensor detection circuit 11 or the heat ray sensor slave signal circuit 12. On the other hand, the CPU 10 is in a state where the brightness detected by the brightness sensor is darker than a predetermined brightness level, the output of the heat ray sensor detection circuit 11 exceeds the threshold value, or there is a detection input from the heat ray sensor slave unit signal circuit 12. Then, an interrupt signal is transmitted from the multiplex transmission signal transmitting / receiving circuit 14, and after passing through the above-described transmission procedure, the data (P1) of the ON address is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1.
[0080]
Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14, and returns the data (P2) of the OFF address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and thins the lighting fixture 5 in the illumination range set by the pattern P2. .
[0081]
Next, when the current time counted by the timer circuit 19 becomes an extinguishing time (for example, 23:00), the CPU 10 sends out an interrupt signal from the multiplex transmission signal transmitting / receiving circuit 14, and after passing through the above-described transmission procedure, data of the extinguishing address ( P3) is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns off all the luminaires 5 set in the pattern P3 (FIG. 18 (d)).
[0082]
In addition, if there is a detection input from the hot wire sensor detection circuit 11 after the extinction time has passed and before the recovery time (for example, 06:00) comes, the CPU 10 causes the multiplex transmission signal transmission / reception circuit 14 to send out an interrupt signal. After the above transmission procedure, the ON unit data (P1) is returned to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns on the plurality of lighting fixtures 5 in a pattern P1. Thereafter, when a predetermined operation holding time elapses after the detection input is lost, the CPU 10 sends an interrupt signal from the multiplex transmission signal transmission / reception circuit 14 and returns the data (P3) of the extinction address after passing through the above transmission procedure. It is returned to the transmission unit 1 as a signal. At this time, the transmission unit 1 sends control data to the corresponding relay control terminal 4 based on the return signal received from the automatic switch 2 with a heat ray sensor, and turns off all the luminaires 5 set in the pattern P3.
[0083]
  Thereafter, when the current time counted by the timer circuit 19 has passed the recovery time set in the nonvolatile memory 18, the CPU 10 turns off the luminaire 5 when the operation holding time has elapsed from the detection input when there is a detection input. Control is performed according to the control content of the OFF address (that is, the lighting fixture 5 is dimmed). The operation when delay control is performed (see FIG. 18 (e))Switch described in Basic Configuration 1Since this is the same, the description thereof is omitted. If the recovery time is not set in the nonvolatile memory 18, the control operation returns to the original control operation when the ambient illuminance detected by the brightness sensor becomes brighter than the reference brightness level. When the operation holding time has elapsed from the detection input, the lighting fixture 5 is controlled by the control content of the OFF address.
[0084]
  Mentioned aboveBasic configuration 1 switchThen, it is unnecessary to be dark at night, or because the image is bad, the lighting fixture 5 is fully lit based on the control contents of the ON address until the operation holding time elapses from the detection input, and then the OFF address Depending on the control details, the lighting is turned off or dimmed, but because there are few people in the middle of the night, it is necessary to turn off the lighting fixtures that are turned on or dimmed for energy saving. desirable. Therefore, in the present embodiment, it is possible to set a turn-off time for performing control such that the lighting fixture 5 is turned off after the operation holding time has elapsed, and in a desired time zone, the lighting fixture 5 is completely turned off to save energy. I am trying.
[0085]
  Here, also in this embodimentSwitch described in Basic Configuration 1You can adjust the value of the setting items related to the operation as well as the ON address, OFF address, ON / OFF address, delay address, operation holding time, operation delay time, and brightness level as setting items And the time to start control by the extinguishing address after the operation holding time has elapsed (extinguishing time), the address to be controlled after the extinguishing time (extinguishing address), the time to enable control by the OFF address (recovery time), the current The time can be adjusted. 19A to 19K show display examples of the liquid crystal display unit 16a. The contents of the setting items are displayed on the upper side of the screen, and the values are displayed on the lower side of the screen. The operation buttons 17c, By pressing 17d, the display of the display items is switched in a predetermined order, and the setting value of each setting item can be confirmed. 19A is an ON address display screen, FIG. 19B is an OFF address display screen, FIG. 19C is an on / off address display screen, and FIG. 19D is a delay address display screen. 19 (e) is an operation holding time display screen, FIG. 19 (f) is an operation delay time display screen, FIG. 19 (g) is a brightness level display screen, and FIG. 19 (h) is an extinguishing time display screen. FIG. 19 (i) is a display screen for the unlit address, FIG. 19 (j) is a display screen for the recovery time, and FIG. 19 (k) is a display screen for the current time. The procedure to set the value of each setting item isBasic configuration 1 switchSince this is the same, the description thereof is omitted.
[0086]
  (Basic configuration 3)
  Of the present inventionBasic configuration 3Will be described with reference to FIGS.
[0087]
  This automatic switch with heat ray sensorThenDescribed in Basic Configuration 1In the automatic switch with a heat ray sensor, the sensitivity level of the heat ray sensor is added as a setting item related to the operation. The structure and operation of an automatic switch with a heat ray sensorBasic configuration 1 switchTherefore, the same components are denoted by the same reference numerals, and illustration and description thereof are omitted.
[0088]
  This switchAlso inBasic configuration 1 switchYou can adjust the value of the setting items related to the operation as well as the ON address, OFF address, ON / OFF address, delay address, operation holding time, operation delay time, and brightness level as setting items And the sensitivity level can be adjusted. 20A to 20H show display examples of the liquid crystal display unit 16a. FIG. 20A shows an ON address display screen, FIG. 20B shows an OFF address display screen, and FIG. ) Is an on / off address display screen, FIG. 20D is a delay address display screen, FIG. 20E is an operation holding time display screen, FIG. 20F is an operation delay time display screen, and FIG. g) is a brightness level display screen, and FIG. 20H is a sensitivity level display screen. The content of the setting item is displayed on the upper side of the screen, and the value is displayed on the lower side of the screen. The procedure for setting the value of each setting item is as follows:Basic configuration 1 switchSince this is the same, the description thereof is omitted.
[0089]
Here, the set value of the sensitivity level is stored in the nonvolatile memory 18, and the CPU 10 uses this set value as a threshold value for detection input from the heat ray sensor detection circuit 11. FIG. 21A shows the detection input from the heat ray sensor detection circuit 11, and FIGS. 21B, 21C and 21D show the determination results when the sensitivity levels are set to low, medium and high, respectively. The lower the sensitivity level (that is, the higher the threshold value), the more difficult it is to detect heat rays.
[0090]
  If the detection sensitivity of the heat ray sensor is fixed, it is difficult to detect heat rays in places where the detection distance is long or where the ambient temperature is high, and conversely, false detection is likely in places where there is a flow of air.switchSince the detection sensitivity of the heat ray sensor can be adjusted, the detection sensitivity can be detected with the detection sensitivity corresponding to the installation location by increasing the detection sensitivity in the former case and decreasing the detection sensitivity in the latter case.
[0091]
  (Basic configuration 4)
Of the present inventionBasic configuration 4Will be described with reference to FIGS. The configuration and operation of the automatic switch 2 with a heat ray sensorSwitch described in Basic Configuration 1Since this is the same, the description thereof is omitted.
[0092]
  FIG.Is heatIt is a system configuration diagram of a remote monitoring control system using an automatic switch 2 with a line sensor,This switchThen, a terminal device 7 for adjusting the operation holding time, a terminal device 8 for adjusting the operation delay time, and a terminal device 9 for adjusting the reference brightness level are connected to the signal line Ls. is there. Each of the terminals 7 to 9 has an up button Sa and a down button Sb that raise or lower the value of the setting item, a level display portion Lv that displays the current setting value as a level, and an ON that is operated when determining the setting value. / Off button Sc is provided, and the value of each setting item can be set using these terminals 7-9.
[0093]
  Here, the non-volatile memory 18 of the automatic switch 2 with a heat ray sensor has, as setting items, an ON address, an OFF address, an on / off address, a delay address, an operation holding time, and an address for adjusting the operation holding time. (Operation hold address), operation delay time, address for adjusting the operation delay time (operation delay address), brightness level, and address for adjusting the brightness level (brightness address) It can be set. 23A to 23J show display examples of the liquid crystal display unit 16a. FIG. 23A shows an ON address display screen, FIG. 23B shows an OFF address display screen, and FIG. ) Is an on / off address display screen, FIG. 23 (d) is a delay address display screen, FIG. 23 (e) is an operation holding time display screen, FIG. 23 (f) is an operation holding address display screen, and FIG. g) is an operation delay time display screen, FIG. 23 (h) is an operation delay address display screen, FIG. 23 (i) is a brightness level display screen, and FIG. 23 (j) is a brightness address display screen. The contents of the setting items are displayed on the upper side of the screen, and the values are displayed on the lower side of the screen. The procedure for setting the value of each setting item is as follows:Switch described in Basic Configuration 1Since this is the same, the description thereof is omitted. in this way,This switchThe operation holding address, the operation delay address, and the brightness address can be set, and these addresses are assigned to the terminals 7-9.
[0094]
When the up button Sa and the down button Sb as input means included in each terminal device 7-9 are pressed, an interrupt signal is sent from each terminal device 7-9, and each setting item after passing through the above transmission procedure. An up signal that gradually increases the value of or a down signal that gradually decreases is returned to the transmission unit 1 as a return signal. The transmission unit 1 sends control data to the automatic switch 2 with a heat ray sensor based on the return signals received from the terminals 7 to 9, and the CPU 10 gradually sets the corresponding setting item values in the automatic switch 2 with a heat ray sensor. While increasing / decreasing, the liquid crystal display circuit 16 is used to display the value on the liquid crystal display unit 16a. In each of the terminals 7 to 9, while the up button Sa or the down button Sb is kept pressed, the display of the level display portion Lv is increased or decreased, and when the up button Sa or the down button Sb is released, each terminal device An interrupt signal is sent from 7 to 9, and a stop signal for stopping the increase / decrease in the setting items after the above transmission procedure is sent back to the transmission unit 1 as a return signal. At this time, the transmission unit 1 sends control data to the automatic switch 2 with a heat ray sensor based on the return signals received from the terminals 7 to 9, and the CPU 10 as a setting unit corresponds to the automatic switch 2 with a heat ray sensor. The increase / decrease in the value of the setting item is stopped, and the current value is stored in the nonvolatile memory 18. In addition, after adjusting the value of the setting item in each terminal device 7 to 9 to a desired value, when the ON / OFF button Sc is pressed once, the display of the level display portion Lv is turned off, and when pressed again, the level display portion Lv Is turned on, and the current set value is set to the median value displayed on the level display portion Lv.
[0095]
  Switch described in Basic Configuration 1Then, since the setting work is performed using the operation parts 17a to 17d provided on the switch body, when the setting is changed after the construction, the changing work must be performed on the ceiling surface.This switchThen, since the value of the setting item of the automatic switch 2 with a heat ray sensor is adjusted using the terminals 7 to 9 connected to the signal line Ls, the setting work can be performed on the wall surface, and the desired setting can be performed from a remote place. The value of the setting item can be easily adjusted. Moreover, since each terminal device 7-9 has the structure similar to the existing light control operation terminal device, a setting operation | work can be performed using the existing terminal device.
[0096]
  (Basic configuration 5)
  Of the present inventionBasic configuration 5Will be described with reference to FIGS.
[0097]
  This switchThenDescribed in Basic Configuration 1In the automatic switch 2 with a heat ray sensor, a light emitting / receiving window 20 of a wireless transmitting / receiving unit that transmits and receives a wireless signal such as an infrared signal is provided on the lower surface of the body 21, and a light emitting diode and a photodiode are arranged on the back side of the light emitting / receiving window 20 It is. Then, the value of the setting item transmitted by the wireless signal from the wireless setting device 50 is received by the wireless transmission / reception unit, and the CPU 10 as the setting unit stores the value of the received setting item in the non-volatile memory 18, and The value of a desired setting item can be set from the location.
[0098]
FIG. 25 is an external view of the wireless setting device 50, and FIG. 26 is a block diagram of the wireless setting device. The device of the wireless setting device 50 is formed in a size that can be gripped by hand, and the inside of the device is a micro-device. A signal processing unit 51 mainly composed of a computer (hereinafter abbreviated as a microcomputer) is accommodated. The signal processing unit 51 temporarily stores a program memory 60a composed of a flash memory storing a system program, a data memory 60b composed of a flash memory storing data created when setting the above setting items, and the like. A working memory 60c made of SRAM for storing power data is connected through a data bus BDT and an address bus BAD. Here, since the flash memory retains the stored contents even when there is no power supply, the program stored in the program memory 60a and the setting item data stored in the data memory 60b can be retained even after the power is turned off. it can.
[0099]
A liquid crystal display 53 is connected to the signal processing unit 51, and the liquid crystal display 53 is disposed on the upper front of the container. The liquid crystal display 53 includes a backlight, and the light emission luminance of the backlight is controlled by a backlight control circuit 54. The backlight is instructed to be turned on / off by the backlight switch S12.
[0100]
The signal processing unit 51 is connected to four operation buttons 61a to 61d for performing setting item selection operations and setting value input operations. The operation buttons 61a to 61d are arranged at the lower front of the body. Has been. The operation button 61a is a button for performing a determination operation, the operation button 61b is an ESC button for performing a cancel operation, and the operation buttons 61c and 61d function as setting item switching buttons when a setting item is selected. When inputting a value, the operation button 61c functions as a button for increasing the value of the setting item, and the operation button 61d functions as a button for decreasing the value of the setting item. In addition, a confirmation button 62a that is operated when confirming a current set value and a setting button 62b that is operated when performing a setting item setting operation are arranged on the front of the container.
[0101]
An optical transmission / reception circuit 55 that projects and receives an optical wireless signal using infrared as a medium is also connected to the signal processing unit 51. The optical transmission / reception circuit 55 includes a light emitting diode and a photodiode for projecting and receiving infrared rays. A light projecting / receiving window 55c that transmits infrared rays is mounted on the upper surface of the container, and a light emitting diode and a photodiode are arranged on the back side of the light projecting / receiving window 55c. In addition, a buzzer Bz for generating a confirmation sound for operation by the operation buttons 61 a to 61 d and a warning sound at the time of an erroneous operation is also connected to the signal processing unit 51.
[0102]
  The signal processing unit 51 is connected to a receptacle 59 for connection to the signal line Ls via the transmission / reception circuit 52 and the power switch S10. The transmission / reception circuit 52 is a circuit that enables data transmission to and from the transmission unit 1 via the signal line Ls of the remote monitoring and control system. In addition to transmitting the set value directly by wireless communication, the transmission / reception circuit 52 is connected via the signal line Ls. Then, the value of the setting item can be transmitted to the transmission unit 1 and the value of the setting item can be set to the automatic switch 2 with a heat ray sensor via the transmission unit 1. That is, the wireless setting device 50Basic configuration 4It has the same function as the terminals 7 to 9 described in the above.
[0103]
The receptacle 59 is formed in a jack shape, for example, and when connecting the wireless setting device 50 to the signal line Ls, a connection line (not shown) having a connector that is detachably coupled to the receptacle 59 at one end is used. The other end of the connection line is electrically connected to the signal line Ls.
[0104]
When the wireless setting device 50 is connected to the signal line Ls via the receptacle 59, an internal power supply can be obtained by rectifying and stabilizing the transmission signal transmitted to the signal line Ls. Further, when not connected to the signal line Ls, a built-in battery (not shown) can be used as a power source. Therefore, in the power supply circuit 56 for supplying power to the internal circuit, one of the power from the signal line Ls and the power from the battery is selected and supplied to the internal circuit. Here, whether or not it is connected to the signal line Ls is determined by whether or not a transmission signal is input to the signal presence / absence detection circuit 57. Further, the wireless setting device 50 is provided with a battery remaining amount detection circuit 58 for detecting the remaining battery capacity.
[0105]
  Here, when setting the value of each setting item, if the setting button 62b is pressed, the liquid crystal display 53 is displayed.Basic configuration 1A setting screen similar to that described above is displayed. When the operation buttons 61a to 61d are operated on the setting screen to input desired values and then the setting button 62 is pressed, the setting values of the setting items are transmitted from the optical transmission / reception circuit 55 by wireless signals. At this time, in the automatic switch 2 with a heat ray sensor, the wireless transmission / reception unit receives the setting value transmitted by the wireless signal, and the CPU 10 stores the value of the setting item in the nonvolatile memory 18. Further, when confirming the setting value of each setting item, the current setting value is requested from the optical transmission / reception circuit 55 by pressing the confirmation button 62a after operating the operation buttons 61a to 61d to select a desired setting item. The signal to be transmitted is transmitted as a wireless signal. In the automatic switch 2 with a heat ray sensor, when the wireless transmission / reception unit receives a request signal transmitted as a wireless signal, the CPU 10 reads the current set value from the non-volatile memory 18 based on the request signal and transmits it from the wireless transmission / reception unit. At this time, in the wireless setting device 50, the optical transmission / reception circuit 55 receives the setting value transmitted by the wireless signal, and displays the received setting value on the liquid crystal display 53. The set value of can be confirmed.Basic configuration 1 switchThen, since the setting work is performed using the operation parts 17a to 17d provided on the switch body, when the setting is changed after the construction, the changing work must be performed on the ceiling surface.This switchThen, since the value of the setting item of the automatic switch 2 with a heat ray sensor is adjusted using the wireless setting device 50, the value of the desired setting item can be adjusted at hand.
[0106]
By the way, although the wireless setting device 50 shown in FIGS. 25 and 26 is dedicated for setting the setting items related to the operation of the automatic switch 2 with a heat ray sensor, it sets address data as shown in FIGS. 27 and 28. The wireless setting device 50 ′ may have a function of setting the setting items of the automatic switch 2 with a heat ray sensor.
[0107]
The configuration of the wireless setting device 50 ′ is substantially the same as the wireless setting device 50 described above, but an operation button including four operation buttons 61a to 61d for setting predetermined setting items of the automatic switch 2 with a heat ray sensor. In addition to 61, an address setting button 64 comprising a plurality of operation buttons for setting address data is provided, and the address setting button 64 and the operation button 61 are arranged on the front side of the body separately. It is.
[0108]
  Also bookswitchThen, the optical transmission / reception circuit 55 is composed of the address setting optical transmission / reception circuit 55a used when setting the address data and the heat ray sensor setting optical transmission / reception circuit 55b used when setting the setting items in the automatic switch 2 with heat ray sensor. Yes, the optical transmission / reception circuit switching unit 63 switches the transmission / reception circuit according to the set content. In the address setting optical transmission / reception circuit 55a, in order to prevent the setting data from being received by another unintended terminal, the current flowing to the light emitting element is reduced and the sensitivity of the light receiving element is lowered to reduce the communication distance. It is shortened. On the other hand, since the automatic switch 2 with a heat ray sensor is embedded and fixed in the ceiling, it is necessary to increase the transmission output when setting data is transmitted to the automatic switch 2 with a heat ray sensor. Then, while increasing the electric current sent to a light emitting element, the sensitivity of a light receiving element is raised and the communication distance is lengthened.
[0109]
Thus, since the wireless setting device 50 ′ for address setting has a function of setting the setting items of the automatic switch 2 with a heat ray sensor, the address data and the heat ray sensor are attached with one wireless setting device 50 ′. Both set values relating to the operation of the automatic switch 2 can be set, and there is no need to have two setters.
[0110]
【The invention's effect】
  As described above, the invention of claim 1 connects a plurality of terminals each having individual address data set to a signal line, and transmits a transmission signal including address data from a transmission unit connected to the signal line. Each terminal is individually accessed by sending it to the line in a time division multiplex transmission system, and when the transmission unit receives monitoring data from any terminal during the signal return period set in synchronization with the transmission signal, Control data is created based on the monitoring data, and the control data is transmitted by the transmission signal to the terminal device in which the correspondence relationship between the terminal device that generated the monitoring data and the address is set. ByLighting equipment that is a loadUsed in a remote monitoring and control system that controls the operation of the sensor, a heat ray sensor unit that detects a heat ray emitted from a human body within a predetermined detection area, and a transmission signal that is connected to the signal line by a time division multiplex transmission method A transmission communication unit, a signal processing unit that outputs monitoring data for controlling a load based on a detection input of the heat ray sensor unit, a transmission control unit that transmits monitoring data output from the signal processing unit from the transmission communication unit, and each unit The switch body that is housed and the heat ray sensor part is placed on the front face, and the front face is exposed and embedded in the mounting hole provided on the ceiling surface, and the part other than the heat ray sensor part on the front face of the switch body is attached and detached A switch button for switching a setting item to any one of a plurality of setting items related to the operation of each part according to a pressing operation. Set value input unit for increasing or decreasing the value of the switched setting item Ri, and a display unit for displaying the value to be adjusted is arranged in the region covered by the decorative cover on the front switch body using a set value input unitThe signal processing unit turns on the luminaire at a predetermined illuminance level when the heat ray sensor unit detects a heat ray in a time other than the preset turn-off time period, and also after the heat ray sensor unit no longer detects the heat ray When the operation holding time has elapsed, the illuminance level is reduced, and the lighting is continued at the reduced illuminance level. , The lighting device is controlled to be extinguished when a predetermined operation holding time has elapsed since the heat ray sensor unit no longer detects the heat ray, and the setting items are the start time and end time of the extinguishing time zone IsWhen the value of the setting item is increased or decreased using the setting value input unit, the value is displayed on the display unit, so that the value of the setting item can be accurately set to the desired value while observing the value on the display unit. Can be set. In addition, the set value input unit and display unit are located on the front of the switch body and covered with a decorative cover that can be detachably attached to the switch body, so if the decorative cover is removed, the switch body remains attached to the ceiling surface. Work can be performed, and since the cover is always covered with a makeup cover, the setting value can be prevented from being changed due to mischief and the appearance can be improved.There is also an effect that the start time and end time of the turn-off time zone can be set accurately.
[0111]
According to a second aspect of the present invention, in the first aspect of the present invention, the signal line is connected to a setting terminal having input means for inputting the value of the setting item, and the transmission unit is a setting terminal. When the monitor receives the monitoring data generated in response to the input operation of the input means, it creates control data for setting the value of the setting item according to the received monitoring data, and transmits the created control data using a transmission signal And a setting unit for setting a setting item value according to control data included in the transmission signal received by the transmission communication unit, and a setting terminal connected to the signal line. It is possible to set a desired setting item value from a remote location.
[0112]
According to a third aspect of the present invention, in the first aspect of the invention, a wireless receiving unit that receives a setting value transmitted by a wireless signal from an external setting device, and a setting unit that sets a value of a setting item received by the wireless receiving unit And a desired setting item value can be set from a remote location using a setting device that transmits the setting item value by a wireless signal.
[0113]
  The invention of claim 4 is the invention according to any one of claims 1 to 3.,UpThe setting item is the operation holding time, and the operation holding time can be set accurately.
[0114]
According to a fifth aspect of the present invention, in any one of the first to third aspects of the present invention, the setting item includes a start time of a time zone in which the signal processing unit performs a control operation according to a detection input of the heat ray sensor unit, and It is an end time, and the time zone in which the control operation is performed can be accurately set according to the detection input of the heat ray sensor unit.
[0116]
  Claim6According to the present invention, in any one of the first to third aspects, the setting item is a detection sensitivity of the heat ray sensor unit, and the sensitivity can be changed according to the installation location.
[0117]
  Claim7The invention according to any one of claims 1 to 3 is characterized in that the setting item is address data, and it is not necessary to prepare a separate setting unit for the address data, and an automatic switch with a heat ray sensor is provided. The address data can be set with.
[Brief description of the drawings]
[Figure 1]Basic configuration 1The automatic switch with a heat ray sensor is shown, (a) is a bottom view with the plate removed, and (b) is a side view.
FIG. 2 is an exploded perspective view of the above.
FIG. 3 is a block diagram of the above.
FIG. 4 is a system configuration diagram of a remote monitoring control system using the same as above.
FIGS. 5A to 5C are explanatory diagrams of transmission signals used in the above.
FIGS. 6A to 6D are time charts for explaining the operation described above.
FIGS. 7A to 7G are explanatory diagrams of a display screen of the liquid crystal display unit. FIG.
FIGS. 8A to 8F are explanatory diagrams of an OFF address setting procedure same as the above.
FIGS. 9A to 9G are explanatory diagrams of the operation holding time setting procedure.
FIGS. 10A to 10D are time charts for explaining another operation of the above.
FIGS. 11A to 11H are explanatory diagrams of a display screen of the liquid crystal display unit of the above.
FIG.Basic configuration 2It is a block diagram of an automatic switch with a heat ray sensor.
FIGS. 13A to 13D are time charts for explaining the operation described above.
FIGS. 14A to 14I are explanatory diagrams of a display screen of the liquid crystal display unit of the above.
FIGS. 15A to 15D are time charts illustrating another operation of the above.
FIGS. 16A to 16J are explanatory diagrams of a display screen of the liquid crystal display unit of the above.
FIG. 17 is an embodiment.1It is a block diagram of an automatic switch with a heat ray sensor.
18A to 18E are time charts for explaining the operation of the above.
FIGS. 19A to 19K are explanatory diagrams of display screens of the liquid crystal display unit of the above.
FIG. 20 (a) to (h)Basic configuration 3It is explanatory drawing of the display screen of the liquid crystal display part of the automatic switch with a heat ray sensor.
FIG. 21 is an explanatory diagram for explaining the operation described above.
FIG. 22Basic configuration 4It is a system block diagram of the remote monitoring control system using the automatic switch with a heat ray sensor of this.
FIGS. 23A to 23J are explanatory diagrams of a display screen of the liquid crystal display unit of the above.
FIG. 24Basic configuration 5The automatic switch with a heat ray sensor is shown, (a) is a bottom view with the plate removed, and (b) is a side view.
FIG. 25 is an external view of a wireless setting device used in the above.
FIG. 26 is a block diagram of the above.
FIG. 27 is an external view of another wireless setting device used in the above embodiment.
FIG. 28 is a block diagram of the above.
[Explanation of symbols]
  2 Automatic switch with heat ray sensor
  16a Liquid crystal display
  17a-17d Operation buttons
  21 body
  24 Cover
  25 plates
  27 Rotating body

Claims (7)

A plurality of terminals each having individual address data set are connected to a signal line, and a transmission signal including address data is sent to the signal line from the transmission unit connected to the signal line by a time division multiplex transmission method. Thus, each of the terminals is accessed individually, and when the transmission unit receives monitoring data from any of the terminals during a signal reply period set in synchronization with the transmission signal, the transmission unit obtains control data based on the monitoring data. The control data is transmitted by the above transmission signal to the terminal device for which the correspondence relationship between the terminal device that has created and generated the monitoring data and the address is set, and the operation of the luminaire that is a load by the received control data in the terminal device Used in a remote monitoring and control system that controls a heat ray sensor unit that detects a heat ray emitted from a human body in a predetermined detection area, and connected to the signal line A transmission communication unit that transmits and receives transmission signals by a time division multiplex transmission method, a signal processing unit that outputs monitoring data for controlling a load based on a detection input of the heat ray sensor unit, and monitoring data output by the signal processing unit A transmission control unit for transmitting from the transmission communication unit, and a switch body that houses each of the above units, and the heat ray sensor unit is disposed on the front surface, and is embedded in a mounting hole provided on the ceiling surface with the front surface exposed. And a decorative cover that detachably covers a part other than the heat ray sensor part on the front surface of the switch body, and a switching button for switching an item to be set to any of a plurality of setting items related to the operation of each part, by the switching button A setting value input unit that increases or decreases the value of the switched setting item according to the pressing operation, and a display unit that displays a value adjusted using the setting value input unit are switched. Yes disposed in a portion covered by the decorative cover Ji front panel, the signal processing section, with the outside preset off time period to turn on the a luminaire hot wire sensor unit detects the heat rays at a predetermined illuminance level, The illuminance level is lowered when a predetermined operation holding time has elapsed since the heat ray sensor unit no longer detects the heat ray, and the light ray sensor unit continues to be lit at the reduced illuminance level. When detected, the lighting equipment is turned on at a predetermined illuminance level, and the lighting equipment is turned off when a predetermined operation holding time has elapsed since the heat ray sensor unit no longer detects the heat rays. An automatic switch with a heat ray sensor of a remote monitoring control system, characterized in that items are a start time and an end time of the extinguishing time zone . The signal line is connected to a setting terminal having input means for inputting the value of the setting item, and the transmission unit has monitoring data generated by the setting terminal in response to an input operation of the input means. Control data for setting the value of the setting item is generated according to the received monitoring data, and the generated control data is transmitted by a transmission signal, and the transmission signal is received by the transmission communication unit. 2. The automatic switch with a heat ray sensor for a remote monitoring control system according to claim 1, further comprising a setting unit configured to set a value of a setting item in accordance with control data contained therein. 2. The wireless receiving unit that receives a setting value transmitted by a wireless signal from an external setting device, and a setting unit that sets a value of a setting item received by the wireless receiving unit. Automatic switch with heat ray sensor for remote monitoring and control system. Automatic switch with heat ray sensor of the remote monitoring control system according to any one of claims 1 to 3, wherein the upper Symbol setting item is the operation holding time. The said setting item is the start time and end time of the time slot | zone when a signal processing part performs control operation according to the detection input of a heat ray | wire sensor part, Either of Claim 1 thru | or 3 characterized by the above-mentioned. Automatic switch with heat ray sensor of remote monitoring control system described. The automatic switch with a heat ray sensor of the remote monitoring control system according to any one of claims 1 to 3, wherein the setting item is a detection sensitivity of a heat ray sensor unit . 4. The automatic switch with a heat ray sensor for a remote monitoring control system according to claim 1, wherein the setting item is address data .

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