JP2023063713A - Switch control device and switch control method - Google Patents

Abstract

To operate an external electric apparatus as expected.SOLUTION: A control unit 31 has transmitted a control signal to a drive unit 34 and turned off a wall switch 21, but actually has failed to drive. It corresponds to detecting malfunction of driving the switch based on a detection result of carbon dioxide concentration, when the wall switch 21 remains on. Therefore, it corresponds to the fact that the control unit outputs the control signal to the drive unit, when a malfunction detection unit detects a malfunction, while configuring the malfunction detection unit by the processing of steps S114 to S118.SELECTED DRAWING: Figure 2

Description

The present invention relates to a switch control device and switch control method for driving a switch of an external device, which is a device to be controlled, based on a predetermined detection result.

2. Description of the Related Art In recent years, remote control devices capable of physically operating switches provided in equipment have been used. For example, push down a seesaw type switch provided on the wall, or push down a push button power switch of an electrical appliance. This remote control device is provided with an actuator for depressing and an operation piece reciprocated by the actuator, and the operation piece is pressed against a switch piece of the device to turn on the power. Remote controls are often connected to WiFi and controlled by the user's smart phone.

https://www.switchbot.jp/

A conventional remote control device displaces an operation piece by pressing it against a switch piece. However, since the remote control device is usually fixed to the switch with double-sided tape or the like, it is difficult to completely fix it. For this reason, slight rattling tends to occur, and once in a while, the switch piece cannot be sufficiently displaced as planned, and as a result, the switching state of the switch does not change. Then, it happened that the electrical equipment did not work as expected.

The present invention provides a switch control device and a switch control method that operate an external electrical device as expected.

The present invention provides a switch control device for driving a switch of an external device, which is a device to be controlled, based on a predetermined detection result, comprising: a drive unit for driving the switch of the external device; a control unit for outputting a control signal for driving the switch; and a malfunction detection unit for detecting a malfunction in driving the switch. It is configured to output the control signal to the driving section.

In the present invention configured as described above, the switch of the external device, which is the device to be controlled, is driven based on the predetermined detection result. Specifically, when the control unit outputs a control signal for driving the driving unit based on the detection result, the driving unit drives the switch of the external device. Further, the malfunction detection section can detect malfunction of the switch drive, and when the malfunction detection section detects malfunction of the switch drive, the control section outputs a control signal to the drive section. The drive unit drives the switch of the external device upon receiving the control signal.
In this manner, even if the switch is erroneously driven, the erroneous operation can be eliminated because the switch is driven again.

In another embodiment of the present invention, a sensor for outputting the detection result is provided, and the malfunction detection section detects malfunction of driving the switch based on the detection result of the sensor.
The present invention configured as described above includes a sensor and outputs the detection result. The erroneous operation detection unit detects an erroneous operation of the switch based on the detection result of the sensor. In general, if an external device is driven based on a certain detection result, driving the external device is expected to change the detection result. Therefore, it is possible to estimate the operation status of the external device by evaluating the detection result of the sensor. If there is no change in the detection result even if the switch is driven, it can be determined that the switch has failed to be driven.

In another embodiment of the invention, the sensor is configured to detect one or a combination of temperature, humidity, carbon dioxide concentration, and barometric pressure.
In the present invention configured as described above, the sensor detects one or a combination of temperature, humidity, carbon dioxide concentration, and atmospheric pressure.
When the temperature rises (decreases), the external equipment is activated, when the humidity increases (decreases), the external equipment is activated, when the carbon dioxide concentration increases (decreases), the external equipment is activated, and when the atmospheric pressure increases (decreases) For example, it is possible to operate an external device.

In another embodiment of the present invention, the external device is activated when the switch is driven, and the detection result of the sensor changes when the external device is activated.
In the present invention configured as described above, the external device operates when the switch is driven, and when the external device operates, the detection result of the sensor changes.

In another embodiment of the present invention, a displacement detection section for detecting displacement of the switch is provided, and the malfunction detection section detects malfunction of driving of the switch based on the detection result of the displacement detection section. be.
In the present invention configured as described above, the displacement detection section detects the displacement of the switch. That is, since it is directly detected whether or not the switch is displaced, the malfunction detection section can detect malfunction of the switch drive based on the detection result of the displacement detection section. If displacement is detected, the switch has been driven; if displacement is detected, it can be determined that the switch has been driven as expected; It can be judged that

In another embodiment of the present invention, the displacement detection section is configured to detect the displacement of the switch by image recognition.
In the present invention configured as described above, the displacement detection section performs image recognition processing based on a signal or data representing an image of the switch. The displacement of the switch can be detected based on the result of image recognition.
In another embodiment of the present invention, the switch has an indicator indicating a switching state, and the displacement detection section recognizes display of the indicator by image recognition.

The present invention configured as described above targets a switch provided with an indicator indicating a switching state, and the displacement detection section recognizes the display of the indicator by image recognition. Since the switching state of the switch can be known based on the display, if the switching state does not change even after driving, it can be determined that there has been a malfunction of the drive.
In another embodiment of the present invention, there is provided a controlled device operation recognition unit that recognizes the state of operation of the controlled device, and the malfunction detection unit detects the operation of the switch based on the recognition result of the controlled device operation recognition unit. drive malfunction.

In the present invention configured as described above, the controlled device operation recognition section can recognize the operation status of the controlled device, and the malfunction detection section detects the above-described error based on the recognition result of the controlled device operation recognition section. Detect malfunction of switch drive.
While the present invention can be recognized as an apparatus, the inventive concept can also be recognized as a method. Therefore, in another embodiment of the present invention, there is provided a switch control method for inputting a predetermined detection result to drive a switch of an external device, which is a device to be controlled, and performing predetermined control. It is also possible to employ a configuration in which a malfunction is detected and, if the malfunction is detected, the switch of the external device is driven again.

In the present invention, when driving the switch of the external device, which is the controlled device, malfunction of the drive is also detected, and if there is a malfunction, the switch is driven again. Able to operate electrical equipment.

1 is a block diagram of a switch driving device to which a switch control device is applied; FIG. 4 is a flow chart of control in the first embodiment. It is a time chart in the same Example. It is a time chart in the same Example. 4 is a flow chart of control in the second embodiment.

(First embodiment)
Hereinafter, embodiments of the present invention will be described based on the drawings.
FIG. 1 shows a block diagram of a switch driving device to which a switch control device according to an embodiment of the present invention is applied.
In the figure, the controlled device 10 is an external device, and the wall switch section 20 corresponds to the switch of the external device. The controlled device 10 corresponds to, for example, a ventilation fan. This ventilating fan is connected to a wall switch section 20 installed on the wall of the building, and is operated or stopped when a movable piece (not shown) of the wall switch 21 of the wall switch section 20 is manually operated by a person. can be

As the movable piece of the wall switch 21, there are generally a seesaw type and a push button type. The former is called a rocker switch, and when a person moves the rocker piece left and right or up and down, the contact turns on and off. The latter is called an alternate switch or an alternate switch, and the movable piece is supported in a floating state by a spring member, and the contact is maintained in the ON state each time one operation of pushing and returning is repeated, or , is maintained in the off state. The first embodiment controls on the premise of a rocker switch. The Panasonic Cosmo series (registered trademark) switches are known as alternate switches.

The wall switch indicator 22 is a small LED that lights when the contact of the wall switch 21 is on and goes off when the contact is off. Other display elements may be used as long as they represent lighting or extinguishing. The wall switch indicator 22 is an example for easily identifying the switching state of the contact of the wall switch 21. In the case of a rocker switch, it is also possible to identify the state of the contact of the wall switch 21 based on the position of the movable piece. A wall switch indicator 22 is not required as it is possible.

The switch control section 30 drives the movable piece of the wall switch 21 based on a predetermined control signal, and corresponds to a switch control device that drives the switch of the external device. The control unit 31 of the switch control unit 30 receives a detection signal to be received by the wireless transmission/reception unit 33 via the antenna 32, and outputs a control signal to the drive unit 34 based on this detection signal. Then, the driving portion 34 reciprocates the arm portion 35 which is swingably supported with a predetermined axis as a fulcrum.

The switch control section 30 is housed in a housing (not shown), and an arm section 35 protruding from the housing swings. The housing is adhered to the panel of the wall switch section 20 with double-faced tape, and the movable piece of the wall switch 21 is caused to reciprocate by swinging the arm section 35 . A rocker switch would need to be reciprocated, and an alternate switch would change from on to off when pushed back and from off to on when pushed back again.

When the arm portion 35 is driven to abut against the movable piece of the wall switch 21, the housing receives a reaction force in the opposite direction. Further, when the arm portion 35 drives the movable piece of the wall switch 21 so as to pull back, the housing receives a reaction force in the direction of being attracted to the movable piece. Since the housing is adhered to the panel of the wall switch 21 with double-sided tape, when the housing receives a reaction force based on the movable piece, there is a predisposition that the housing slightly wobbles due to the elasticity of the double-sided tape.

An arm position recognition unit 36 detects the position of the movable piece of the external wall switch 21 . There are not many situations where the switch control section 30 can always recognize the position of the movable piece of the wall switch 21 by itself. However, when the wall switch indicator 22 is present, the arm position recognition section 36 detects the position of the movable piece of the wall switch 21 . After the driving section 34 outputs a control signal to the arm section 35 to drive the movable piece of the wall switch 21, the recognition signal from the arm position recognition section 36 is input, and the wall switch 21 is moved as intended. If the position of the piece can be detected, the drive section 34 stops the arm section 35 . However, if the position of the movable piece of the wall switch 21 cannot be detected as intended, it is possible that the driving section 34 drives the arm section 35 again.

The sensor measuring device 40 sends a predetermined detection signal to the switch control section 30 . The sensor measuring instrument 40 has a sensor section 41 . The sensor unit 41 measures, for example, carbon dioxide (CO2) concentration and outputs an electrical signal representing the measurement result to the main control unit 42 . Based on the electric signal, the main control unit 42 outputs a control signal to the radio transmission/reception unit 43 so as to output a radio signal representing the concentration of carbon dioxide (CO2). Send a radio signal corresponding to The radio transmitting/receiving section 43 can receive a radio signal corresponding to the control signal via the antenna 44 and outputs the received control signal to the main control section 42 . Further, the main control section 42 outputs a control signal to the display section 45 based on the electric signal representing the measurement result, and the display section 45 can display the carbon dioxide (CO2) concentration and other information. can.
In this embodiment, the sensor unit 41 detects carbon dioxide (CO2) concentration, but it is also possible to use other sensors such as temperature, humidity, and atmospheric pressure. For example, the controlled device 10 (external device) is operated when the temperature rises (falls), the controlled device 10 (external device) operates when the humidity rises (falls), and the atmospheric pressure rises (falls). It can be said that the controlled device 10 (external device) is operated.

The wall switch position recognition unit 50 detects the state of the movable piece of the wall switch 21 by image recognition. The image recognition section 51 includes a camera and an image recognition processing unit, and notifies the control section 52 of the image processing result. Upon receiving the notification of the image processing result, the control unit 52 outputs a control signal to the wireless transmission/reception unit 53 so as to output a wireless signal representing the notification result. Send a corresponding radio signal. Note that the radio transmission/reception unit 53 can receive a radio signal corresponding to the control signal via the antenna 54 and outputs the received control signal to the control unit 52 . For example, when a control signal requesting an image processing result is transmitted to the control unit 52 as a radio signal, the control unit 52 can notify the image recognition unit 51 of the image processing result.

The controlled device operation recognition unit 60 indirectly recognizes the operation status of the controlled device 10 . Assuming that the controlled device 10 is a ventilation fan, the controlled device motion recognition sensor 61 can be an air volume sensor or a vibration sensor. This is because whether or not a ventilation fan is operating can be detected by an air volume sensor or a vibration sensor.
The controlled device motion recognition sensor 61 notifies the control unit 62 of the recognition result as to whether or not there is a motion to be indirectly detected. When the control unit 62 receives the notification of the recognition result of the motion, it outputs a control signal to the wireless transmission/reception unit 63 so as to output a wireless signal representing the notification result. A radio signal corresponding to the control signal is transmitted. Note that the radio transmitting/receiving section 63 can receive a radio signal corresponding to the control signal via the antenna 64 and outputs the received control signal to the control section 62 . For example, when a control signal requesting the recognition result of the presence or absence of motion is transmitted to the control unit 62 as a radio signal, the control unit 62 may cause the controlled device motion recognition sensor 61 to notify the recognition result. It is possible.

Next, the operation of this embodiment having the above configuration will be described.
Before explaining the present switch control device, a feedback control system for the wall switch section 20 and the controlled device 10 by the switch control section 30 and the sensor measuring device 40, for example, will be explained as a premise. If the controlled device 10 is a ventilation fan and the sensor unit 41 of the sensor measuring device 40 is a sensor that detects the concentration of carbon dioxide in the room, the switch control unit 30 will turn on the controlled device 10 when the concentration of carbon dioxide in the room increases. is activated to promote ventilation, and as a result, when the carbon dioxide concentration in the room becomes low, the controlled device 10 is stopped to suppress ventilation. If there is no peculiar situation in the ventilation capacity of the controlled device 10 or the sensitivity of the sensor section 41, this automatic control will not diverge and the carbon dioxide concentration in the room can be maintained within a predetermined range.

However, a situation may occur in which the arm portion 35 cannot drive the movable piece of the wall switch portion 20 as expected. Then, the switch control unit 30 activates the controlled device 10 with the increase in the carbon dioxide concentration in the room as a trigger to promote ventilation, and then waits until the carbon dioxide concentration in the room becomes lower than a predetermined value. It will be. However, since the movable piece of the wall switch section 20 fails to drive, the controlled device 10 does not operate and the carbon dioxide concentration in the room does not decrease. This causes automatic control to fail.

Conversely, the switch control unit 30 stops the controlled device 10 and stops ventilation with the low carbon dioxide concentration in the room as a trigger. will wait for However, since the movable piece of the wall switch section 20 fails to drive, the controlled device 10 does not stop, and the carbon dioxide concentration in the room does not increase. This causes automatic control to fail.
As described above, in the feedback control system on which the present switch control device is based, the automatic control easily fails when the movable piece of the wall switch section 20 fails to drive.

FIG. 2 shows a flow chart of the control in the first embodiment, and FIGS. 3 and 4 show time charts in the same embodiment.
The flowchart mainly corresponds to the control in the control section 31 .

In step S102, when the power is turned on, the following feedback control is started. First, in step S104, initialization is performed. Initialization includes turning off the wall switch 21 in the wall switch section 20 . Then, the operation is started in step S106.
In step S108, the controller 31 determines whether the wall switch 21 is off. The state of the wall switch 21 determined here is a value stored in a memory or the like by the control unit 31, and the actual position need not be acquired by the wall switch position recognition unit 50 each time.

After the initialization, the wall switch 21 is turned off, and "Yes" is determined, and in step S110 it is determined whether or not the carbon dioxide concentration (CO2 value) is greater than the threshold value. Here, the carbon dioxide concentration can be obtained by the sensor measuring device 40 transmitting the measurement result of the sensor unit 41 via the wireless transmitting/receiving unit 43 and the control unit 31 receiving it via the wireless transmitting/receiving unit 33.

If people are active indoors, the carbon dioxide concentration will gradually increase if they are not actively ventilated. For example, when a restaurant is opened and customers enter and start activities, the carbon dioxide concentration gradually increases immediately after initialization. FIG. 3 shows the carbon dioxide concentration versus time during this process (Graph A).
Therefore, in the initial stage, it is determined in step S110 that the carbon dioxide concentration (CO2 value) is not greater than the threshold. Thereafter, in this embodiment, a 5-minute timer is started in step S114, and it is determined in step S116 whether the carbon dioxide concentration is stable at about 400 ppm.

In the initial stage, the carbon dioxide concentration is expected to gradually increase, but when the carbon dioxide concentration is stable at about 400 ppm, the wall switch 21 should have been turned off and stopped. It is predicted that the ventilation fan will actually continue to operate. FIG. 4 shows the carbon dioxide concentration and the passage of time after turning on the ventilation fan. Referring to graph F after 40 hours have elapsed, the carbon dioxide concentration is stable at about 400 ppm.

Thus, if the carbon dioxide concentration is stable at about 400 ppm after starting the 5-minute timer, the control unit 31 outputs a control signal for turning off the wall switch 21 in step S118. is sent to the drive unit 34 to keep the wall switch 21 off, and the control returns to step S106. Originally, the carbon dioxide concentration continues from graph D to graph E in FIG. 4, but by turning it off for the second time, the carbon dioxide concentration continues from graph D to graph F in FIG. is gone. Since the ventilating fan exhausts temperature-controlled air inside the room, failure to stop the ventilating fan increases air conditioning costs.

This phenomenon is caused by the control unit 31 sending a control signal to the drive unit 34 to turn off the wall switch 21, but the drive actually failed, and the wall switch 21 remained on. This corresponds to detection of a malfunction in driving the switch based on the detection result of the carbon dioxide concentration when it was. Therefore, the process of steps S114 to S118 constitutes the malfunction detection section, and the control section outputs a control signal to the drive section when the malfunction detection section detects a malfunction. Further, the sensor measuring device 40 has a sensor that outputs a detection result, and the malfunction detection unit detects a malfunction of the switch drive based on the detection result of this sensor. Of course, the sensor here detects the carbon dioxide concentration.

In addition, the ventilation fan of the controlled device 10, which is an external device, operates when the wall switch 21 is driven. . That is, when the ventilating fan operates, the carbon dioxide concentration decreases, and when the ventilating fan stops, the carbon dioxide concentration begins to rise.

If such an abnormal state does not occur, the carbon dioxide concentration gradually increases. It is determined that it exceeds, and in step S112, the control section 31 transmits a control signal to the drive section 34 to drive the arm section 35 so as to turn on the wall switch 21 . At this time, the controller 31 changes the state of the wall switch 21 to ON and stores it.

In the next step S108, the controller 31 determines that the wall switch 21 is on, and in step S120 determines whether the carbon dioxide concentration (CO2 value) is smaller than the threshold. Since the wall switch 21 was turned on in step S112, it is expected that the carbon dioxide concentration will gradually decrease. FIG. 3 shows a process in which the concentration of carbon dioxide increases, exceeds the threshold value, and then decreases as the ventilation fan is operated (graphs A to B).

In this embodiment, immediately after turning on, it is determined that the carbon dioxide concentration (CO2 value) is not smaller than the threshold in step S120, the 10-minute timer is started in step S124, and the carbon dioxide concentration in step S126. Determine if is increasing. After the wall switch 21 is turned on, the carbon dioxide concentration is expected to gradually decrease as shown in graph B of FIG. When it continues to increase to , it is predicted that the ventilation fan that should have been operated by turning on the wall switch 21 is not actually operating. Therefore, in step S128, the control unit 31 transmits a control signal for turning on the wall switch 21 to the driving unit 34 to keep the wall switch 21 turned on, and the control returns to step S106. . If the wall switch 21 is turned on for the second time, the carbon dioxide concentration will be connected from graph A to graph C, and the carbon dioxide concentration will surely decrease.

This phenomenon is caused by the control unit 31 sending a control signal to the driving unit 34 to turn on the wall switch 21, but the driving actually failed, and the wall switch 21 remained off. This corresponds to detection of a malfunction in driving the switch based on the detection result of the carbon dioxide concentration when it was. Therefore, the process of steps S124 to S128 constitutes the malfunction detection section, and the control section outputs a control signal to the drive section when the malfunction detection section detects a malfunction.

If such an abnormal state does not occur, the carbon dioxide concentration will gradually increase. In step S122, the control section 31 transmits a control signal to the drive section 34 to drive the arm section 35 so as to turn off the wall switch 21. FIG. At this time, the control unit 31 changes the state of the wall switch 21 to off and stores it.

With the above processing, while the wall switch 21 is turned on/off based on the detection result of the carbon dioxide concentration to perform feedback control of the controlled device 10, if an error in driving the wall switch 21 by the drive unit 34 and the arm unit 35 Even if an operation occurs, it is possible to properly detect the malfunction and maintain the original feedback control. In particular, by using the detection result of the carbon dioxide concentration sensor measuring device 40 used in the original feedback control, it is possible to provide an excellent effect that no additional element is required for malfunction detection.

(Second embodiment)
FIG. 5 shows a flow chart of control in the second embodiment.
In this embodiment, the wall switch 21 is an alternate switch.
When compared with the flow chart shown in FIG. 2, the control flow is substantially the same. Although the hundreds digit of the step has been changed from "1" to "2", the contents of steps with the same last two digits are generally the same.

However, in steps S212, S218, S222, and S228 in which the arm portion 35 is moved by the drive portion 34 to drive the movable piece of the wall switch 21, the processing is specialized for the alternate switch. That is, once the movable piece of the alternate switch is pushed and returned, it changes from the ON state to the OFF state, or changes from the OFF state to the ON state. Therefore, in steps S212 and S218 for changing from the off state to the on state, the control section 31 sends only a control signal for "pushing" the wall switch 21 to the driving section 34, and the on state is changed to the off state. Also in steps S222 and S228 for changing, the control section 31 sends only the control signal for "pushing" the wall switch 21 to the drive section .

Also in this second embodiment, the same effect as in the first embodiment can be obtained. In the case of the alternate switch, the drive section 34 always pushes the movable piece of the wall switch 21, so the relationship between the drive section 34, the arm section 35, and the movable piece of the wall switch 21 can be simplified.

(Third embodiment)
In the first and second embodiments, when the wall switch 21 malfunctions, the movable piece of the wall switch 21 is driven again in steps S118, S128, S218, and S228. However, you may choose to sound an alarm.

(Fourth embodiment)
In the above embodiment, feedback control using the detection result of the sensor unit 41 of the sensor measuring instrument 40 is assumed so as to maintain the carbon dioxide concentration within a predetermined range. It uses the detection results of
However, another method may be used to check the position of the movable piece of the wall switch 21 and use the result to detect malfunction.

In this embodiment, in the flowchart shown in FIG. 2, steps S130 and S132, which are branch processes indicated by broken lines, are performed. It also includes the wall switch position recognizing section 50 described in the block diagram shown in FIG. As described above, the image recognition section 51 of the wall switch position recognition section 50 includes a camera and an image recognition processing unit, and notifies the control section 52 of the image processing result.

Suppose that the concentration of carbon dioxide becomes lower than the threshold by turning on the switch of the ventilator, which is the controlled device 10, when the concentration of carbon dioxide becomes higher than the threshold. The control to reach steps S102 to S114 is the same as the above-described control, and therefore will be omitted.
At step S114, a 5-minute timer is started, and at step S116, it is determined whether the carbon dioxide concentration is stable at about 400 ppm. When the carbon dioxide concentration is stable at about 400 ppm, it is predicted that the ventilation fan, which should have been stopped by turning off the wall switch 21, actually continues to operate.

Therefore, in step S130, it is determined whether the switch position is ON. Specifically, the control unit 31 communicates with the wall switch position recognition unit 50 by wireless transmission, and acquires the wall switch position (on position or off position), which is the recognition result of the image recognition unit 51 . Then, if it is found that the wall switch 21 is in the ON position, the control unit 31 transmits a control signal for turning off the wall switch 21 to the driving unit 34 in step S118, thereby turning off the wall switch 21. and control returns to step S106.

Originally, the carbon dioxide concentration continues from graph D to graph E in FIG. 4, but by turning it off for the second time, the carbon dioxide concentration continues from graph D to graph F in FIG. is gone.

This phenomenon is caused by the control unit 31 sending a control signal to the drive unit 34 to turn off the wall switch 21, but the drive actually failed, and the wall switch 21 remained on. This corresponds to detection of an erroneous operation of the switch based on the recognition result of the wall switch position recognition unit 50 when the wall switch position recognition unit 50 detects the malfunction of the switch. Therefore, while configuring the malfunction detection unit by the processing of steps S108 to S118 and S130, the wall switch position recognition unit 50 as the displacement detection unit detects the displacement of the wall switch by image recognition, and the malfunction detection unit detects the displacement. A malfunction of the wall switch 21 is detected based on the detection result of the part.

Next, it is assumed that the carbon dioxide concentration has risen above the threshold as a result of turning off the switch of the ventilation fan, which is the controlled device 10, when the carbon dioxide concentration has fallen below the threshold. The control to reach steps S102 to S108 and S120 to S124 is the same as the control described above, and will be omitted.
A 10-minute timer is started in step S124, and it is determined whether the carbon dioxide concentration continues to increase in step S126. After the wall switch 21 is turned on, the carbon dioxide concentration is expected to gradually decrease as shown in graph B of FIG. When it continues to increase to , it is predicted that the ventilation fan that should have been operated by turning on the wall switch 21 is not actually operating. Therefore, in step S132, the control unit 31 determines whether the switch position is OFF. Specifically, the control unit 31 communicates with the wall switch position recognition unit 50 by wireless transmission, and acquires the wall switch position (on position or off position), which is the recognition result of the image recognition unit 51 . Then, if it is found that the wall switch 21 is in the off position, the control unit 31 transmits a control signal for turning on the wall switch 21 to the driving unit 34 in step S128 to turn the wall switch 21 on. and control returns to step S106.

Originally, the carbon dioxide concentration continues from graph A to graph B in FIG. 3, but by turning it on for the second time, the carbon dioxide concentration continues from graph A to graph C in FIG. is gone.

This phenomenon is caused by the control unit 31 sending a control signal to the driving unit 34 to turn on the wall switch 21, but the driving actually failed, and the wall switch 21 remained off. This corresponds to detection of an erroneous operation of the switch based on the recognition result of the wall switch position recognition unit 50 when the wall switch position recognition unit 50 detects the malfunction of the switch. Therefore, while the malfunction detection unit is configured by the processing of steps S108, S120 to S128, and S132, the wall switch position recognition unit 50, which is a displacement detection unit, detects the displacement of the wall switch by image recognition, and the malfunction detection unit Malfunction of the drive of the wall switch 21 is detected based on the detection result of the displacement detection section.

(Fifth embodiment)
In the above-described fourth embodiment, as described above, the image recognition section 51 of the wall switch position recognition section 50 has a camera and an image recognition processing unit, and detects the displacement position of the wall switch. In this embodiment, the wall switch unit 20 has a wall switch indicator 22, and the state of the wall switch 21 is detected by whether or not the LED is lit.

The flow of control is almost the same as that of the fourth embodiment, and in steps S130 and S132, when judging whether the switch position is ON or OFF, the wall switch indicator 22 is turned on or off. They differ only in that they are

(Sixth embodiment)
In the above-described fourth and fifth embodiments, the wall switch position recognition section 50 detects the displaced position of the wall switch. In this embodiment, malfunction of the drive of the wall switch 21 is detected based on the operation status of the controlled device 10 . Therefore, in the flowchart shown in FIG. 2, steps S140 and S142, which are branch processes indicated by broken lines, are performed. It also includes the controlled device operation recognition unit 60 described in the block diagram shown in FIG. Assuming that the controlled device 10 is a ventilation fan, the controlled device motion recognition sensor 61 of the controlled device motion recognition unit 60 includes an air volume sensor or a vibration sensor.

The flow of control is almost the same as that of the fourth embodiment. Instead of determining whether the switch position is ON or OFF at steps S130 and S132, at steps S140 and S142, the controlled device 10 is turned on or off.
Suppose that the concentration of carbon dioxide becomes lower than the threshold by turning on the switch of the ventilator, which is the controlled device 10, when the concentration of carbon dioxide becomes higher than the threshold. The control to reach steps S102 to S114 is the same as the above-described control, and therefore will be omitted.

At step S114, a 5-minute timer is started, and at step S116, it is determined whether the carbon dioxide concentration is stable at about 400 ppm. When the carbon dioxide concentration is stable at about 400 ppm, it is predicted that the ventilation fan, which should have been stopped by turning off the wall switch 21, actually continues to operate.
Therefore, in step S140, it is determined whether or not the controlled device 10, that is, the ventilation fan is operating. Specifically, the control unit 31 communicates with the controlled device operation recognition unit 60 by radio transmission, and obtains the operation status (operating or stopped) of the non-controlled device, which is the recognition result of the controlled device operation recognition sensor 61. get.

If the controlled device operation recognition sensor 61 is an air volume sensor, the corresponding air volume is detected by the operation of the ventilation fan, and if the controlled device operation recognition sensor 61 is a vibration sensor, the ventilation fan Vibration caused by the rotation of the fan is generated during operation, so the corresponding vibration is detected. It can be recognized whether it is operating or stopped by the fact that these air volumes or vibrations are larger than those at rest.

Then, if it is found that the wall switch 21 is in operation, the control unit 31 transmits a control signal for turning off the wall switch 21 to the driving unit 34 in step S118 to keep the wall switch 21 turned off. , control returns to step S106.
Originally, the carbon dioxide concentration continues from graph D to graph E in FIG. 4, but by turning it off for the second time, the carbon dioxide concentration continues from graph D to graph F in FIG. is gone.

This phenomenon is caused by the control unit 31 sending a control signal to the drive unit 34 to turn off the wall switch 21, but the drive actually failed, and the wall switch 21 remained on. This corresponds to detection of an erroneous operation of the switch based on the recognition result of the controlled device operation recognizing section 60 when it was. Therefore, while configuring the malfunction detection unit through the processing of steps S108 to S118 and S140, the controlled device operation recognition unit 60 recognizes the state of the operation of the controlled device, and the malfunction detection unit recognizes the controlled device operation recognition unit. Based on the recognition result of 60, malfunction of wall switch 21 is detected.

Next, it is assumed that the carbon dioxide concentration has risen above the threshold as a result of turning off the switch of the ventilation fan, which is the controlled device 10, when the carbon dioxide concentration has fallen below the threshold. The control to reach steps S102 to S108 and S120 to S124 is the same as the control described above, and will be omitted.
At step S124, a 10-minute timer is started, and at step S126, it is determined that the carbon dioxide concentration continues to increase. At S126, it is determined whether the carbon dioxide concentration continues to increase. After the wall switch 21 is turned on, the carbon dioxide concentration is expected to gradually decrease as shown in graph B of FIG. When it continues to increase to , it is predicted that the ventilation fan that should have been operated by turning on the wall switch 21 is not actually operating.

Therefore, in step S142, the control unit 31 determines whether the ventilation fan, which is the controlled device 10, is operating. Specifically, the control unit 31 communicates with the controlled device operation recognition unit 60 by radio transmission, and obtains the operation status (operating or stopped) of the non-controlled device, which is the recognition result of the controlled device operation recognition sensor 61. get. Then, if it is found that the wall switch 21 is stopped, the control unit 31 transmits a control signal for turning on the wall switch 21 to the drive unit 34 in step S128 to keep the state of the wall switch 21 turned on. , control returns to step S106.

Originally, the carbon dioxide concentration continues from graph D to graph E in FIG. 4, but by turning it on for the second time, the carbon dioxide concentration continues from graph D to graph F in FIG. is gone.

This phenomenon is caused by the control unit 31 sending a control signal to the driving unit 34 to turn on the wall switch 21, but the driving actually failed, and the wall switch 21 remained off. This corresponds to detection of an erroneous operation of the switch based on the recognition result of the controlled device operation recognizing section 60 when it was. Therefore, while configuring the malfunction detection unit through the processing of steps S108, S120 to S128, and S142, the controlled device operation recognition unit 60 recognizes the state of the operation of the controlled device, and the malfunction detection unit detects the operation of the controlled device. A malfunction of the wall switch 21 is detected based on the recognition result of the recognition unit 60 .

In addition, it cannot be overemphasized that this invention is not what is restricted to the said Example. It goes without saying for those skilled in the art that
・Applying the mutually replaceable members and configurations disclosed in the above examples by appropriately changing the combination ・Although not disclosed in the above examples, it is a known technology and the above examples Appropriately replace the members, configurations, etc. that are mutually replaceable with the members, configurations, etc. disclosed in the above, and apply them by changing the combination ・Although not disclosed in the above examples, known techniques It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as a substitute for the members and configurations disclosed in the above embodiments based on the above, and change the combination and apply it. It is disclosed as

10... controlled device,
20 ... wall switch section,
21 ... wall switch,
22 ... wall switch indicator,
30 ... switch control unit,
31 ... control unit,
32 Antenna,
33... Radio transmitting/receiving unit,
34 ... drive unit,
35 ... arm part,
36 ... arm position recognition unit,
40 ... sensor measuring instrument,
41 ... sensor part,
42 ... main control section,
43... Radio transmitting/receiving unit,
44 Antenna,
45 ... display unit,
50 ... wall switch position recognition unit,
51... Image recognition unit,
52 ... control unit,
53... Radio transmitting/receiving unit,
54 Antenna,
60... Controlled device operation recognition unit,
61 ... controlled device operation recognition sensor,
62 ... control unit,
63... Radio transmitting/receiving unit,
64 Antenna.

Claims (9)

A switch control device that drives a switch of an external device that is a controlled device based on a predetermined detection result,
a driving unit that drives the switch of the external device;
a control unit that outputs a control signal for driving the driving unit based on the detection result;
A malfunction detection unit that detects a malfunction of driving the switch,
The switch control device, wherein the control section outputs the control signal to the drive section when the malfunction detection section detects a malfunction. A sensor that outputs the detection result is provided,
2. The switch control device according to claim 1, wherein the malfunction detection unit detects a malfunction of driving the switch based on the detection result of the sensor. 3. The switch control device according to claim 2, wherein the sensor detects one or a combination of temperature, humidity, carbon dioxide concentration, and atmospheric pressure. 4. The switch control device according to claim 2, wherein the external device operates when the switch is driven, and the detection result of the sensor changes when the external device operates. A displacement detection unit that detects displacement of the switch,
The switch control device according to any one of claims 1 to 4, wherein the malfunction detection section detects malfunction of driving of the switch based on the detection result of the displacement detection section. 6. The switch control device according to claim 5, wherein the displacement detector detects the displacement of the switch by image recognition. 7. The switch control device according to claim 6, wherein the switch has an indicator indicating a switching state, and the displacement detection section recognizes display of the indicator by image recognition. A controlled device operation recognition section for recognizing the operation status of the controlled device is provided, and the malfunction detection section detects a malfunction in driving the switch based on the recognition result of the controlled device operation recognition section. The switch control device according to any one of claims 1 to 7, characterized in that: A switch control method for inputting a predetermined detection result to drive a switch of an external device, which is a device to be controlled, and performing predetermined control,
A switch control method comprising the steps of: detecting a malfunction in driving a switch; and driving the switch of the external device again if the malfunction is detected.

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