JP6899709B2 - Watching system - Google Patents

Description

The present invention relates to a watching system.

In recent years, a management system for managing the physical condition or health of elderly people (hereinafter, also referred to as residents) living in rooms such as long-term care facilities or hospitals has been used. For example, a management system is proposed in which a sensor device installed in the room where the resident lives detects the air component in the room, the server collects the detection result, and the server determines the health risk of the resident. (For example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2006-26037

However, in the technique described in Patent Document 1, the resident needs to wear sensor wear in order to authenticate the resident. Therefore, there is a problem that the health management support system does not function when the resident does not wear the sensor wear.

An object of the present invention is to provide a monitoring system capable of monitoring the situation of a resident with a simple configuration.

The monitoring system of the present invention is a monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device, and is installed in the room. The first device further includes a fan, a gas sensor for detecting a component of air in the room taken in by the fan, and gas data indicating the component detected by the gas sensor. The controller has a communication device that receives the gas data from the first device, and a data analysis unit that analyzes the gas data. the device detects the component of the air in the room, the component sends indicate to gas Sudeta to the controller, the controller, the control signal so that the fan is driven at predetermined intervals first Send to device 1 .
The monitoring system according to another aspect of the present invention is a monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device. A second device installed in the room is further provided, wherein the first device includes a fan, a gas sensor for detecting a component of air in the room taken in by the fan, and the gas sensor detected by the gas sensor. It has a communication device that transmits gas data indicating components to the controller, and the controller has a communication unit that receives the gas data from the first device and a data analysis unit that analyzes the gas data. The second device has a fan, detects a component of air in the room, transmits gas data indicating the component to the controller, and the controller controls the first device and the first device. The fan of the first device and the fan of the second device are controlled according to the arrangement of the second device.
The monitoring system according to another aspect of the present invention is a monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device. A second device installed in the room is further provided, wherein the first device includes a fan, a gas sensor for detecting a component of air in the room taken in by the fan, and the gas sensor detected by the gas sensor. It has a communication device that transmits gas data indicating components to the controller, and the controller has a communication unit that receives the gas data from the first device and a data analysis unit that analyzes the gas data. Then, the second device detects a component of air in the room, transmits gas data indicating the component to the controller, and the first device has a display device, and the display device has a display device. , At least one of a signal, a voice, and an image based on the analysis result of the gas data is output.

According to the present invention, it is possible to provide a monitoring system capable of monitoring the situation of a resident with a simple configuration.

It is a figure which shows schematic the structure of the monitoring system which concerns on Embodiment 1 of this invention. It is a timing chart of a fan of home appliances. It is a flowchart which shows an example of the operation of a controller. It is a figure which shows an example of the combination of the 2nd gas component and the disease associated with the 2nd gas component. It is a flowchart which shows an example of the operation of the home electric appliance at the time of performing the alarming operation. It is a block diagram which shows schematic structure of the monitoring system which concerns on Embodiment 2 of this invention. It is a flowchart which shows an example of operation of each home electric appliance. (A) is a timing chart of a fan of a first home electric appliance, and (b) is a timing chart of a fan of a second home electric appliance.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1.
FIG. 1 is a diagram schematically showing a configuration of a monitoring system 1 according to a first embodiment of the present invention.
The monitoring system 1 includes a home electric appliance 10 as a first device, a controller 200, and an alarm device 100. The monitoring system 1 is a system that detects excrement from the air in the resident's room and detects changes in the resident's health.

The home electric appliance 10 includes a control board 11 which is a control board of the home electric appliance 10, a gas sensor 12, a fan 13, a wireless device 14 as a communication device, a display device 15, and an intake port 16. The home electric appliance 10 is installed in the resident's room and can communicate with the controller 200.

The gas sensor 12 is arranged near the intake port 16. The gas sensor 12 detects a component of air in the room taken into the home electric appliance 10 by the fan 13.

As the fan 13 rotates, the air in the room flows into the home electric appliance 10 from the intake port 16.

The wireless device 14 wirelessly communicates with the controller 200 (specifically, the communication unit 202). For example, the wireless device 14 transmits gas data indicating an air component detected by the gas sensor 12 to the controller 200. Instead of the wireless device 14, a communication device that performs wired communication may be used.

The display device 15 outputs at least one of a signal, a voice, and an image (for example, an alarm signal) based on the analysis result of the gas data for notifying the excrement or the health change of the resident. Further, the display device 15 displays information such as settings of the home electric appliance 10.

The home appliance 10 is, for example, a device such as an electric device installed in a room. As described above, the home electric appliance 10 can communicate with the controller 200 by using the wireless device 14.

The home electric appliance 10 can drive and stop the fan 13 according to a control signal from the controller 200 even while the normal operation (that is, an operation other than the fan 13) is stopped. The home electric appliance 10 can transmit gas data to the controller 200 by using the wireless device 14.

When the fan 13 is driven in the home electric appliance 10, air is concentrated on the gas sensor 12 arranged near the intake port 16, and it is possible to promote the detection of excrement and the detection of health abnormalities.

In the home electric appliance 10, the air around the home appliance 10 is acquired by the gas sensor 12, and the gas data is transmitted to the controller 200 by the wireless device 14.

The controller 200 has a motion sensor 201 for detecting a person, a communication unit 202, and a data analysis unit 203 as a main control unit. The controller 200 is installed in the resident's room. The controller 200 is a HEMS (Home Energy Management System) controller that communicates with the home electric appliance 10 and controls the home electric appliance 10 by using wired communication or wireless communication. The controller 200 can analyze the data and transmit the analysis result to the home electric appliance 10 and the alarm device 100.

The motion sensor 201 is, for example, a pyroelectric sensor that detects the human body by detecting a change in temperature. The motion sensor 201 can detect the presence or absence of a person (resident in the present embodiment) in the room.

The communication unit 202 can communicate with the home electric appliance 10 and the alarm device 100 by wire communication or wireless communication. For example, the communication unit 202 receives gas data from the home electric appliance 10. In addition, the communication unit 202 transmits a notification signal for notifying the detection of excrement or the detection of a health abnormality to the notification device 100.

The data analysis unit 203 is composed of, for example, a processor such as a CPU (Central Processing Unit) and a memory. The data analysis unit 203 analyzes the gas data received from the home electric appliance 10 via the communication unit 202.

The alarm device 100 is a device that outputs at least one of a signal, a voice, and an image based on the analysis result of gas data according to the alarm signal received from the controller 200.

Next, the operation of the home electric appliance 10 will be described.
FIG. 2 is a timing chart of the fan 13 of the home electric appliance 10.
When the value shown on the vertical axis (sensor value) is 1, the fan 13 is driven, and when the value shown on the vertical axis is 0, the fan 13 is stopped.

The drive of the fan 13 is controlled by the controller 200. That is, the controller 200 controls the driving of the fan 13 by transmitting a control signal to the home electric appliance 10 so that the fan 13 is driven at a predetermined interval (for example, an interval of several minutes). Specifically, the wireless device 14 of the home electric appliance 10 receives a control signal from the controller 200, the control board 11 of the home electric appliance 10 receives the control signal via the wireless device 14, and the fan 13 follows the control signal. Control the drive of. The wireless device 14 may convert the control signal received from the controller 200. In this case, the control board 11 controls the drive of the fan 13 according to the control signal received from the wireless device 14 (that is, the control signal converted by the wireless device 14).

The fan 13 is driven and stopped at predetermined intervals, as shown in FIG. When the fan 13 is driven, the air in the room flows into the home electric appliance 10 from the intake port 16, passes through the gas sensor 12, and is discharged from the fan 13 to the outside of the home electric appliance 10. As a result, the home electric appliance 10 can efficiently collect the air in the room.

The abnormality detection operation of the controller 200 using the gas data acquired from the home electric appliance 10 will be described. The incident detection operation is an operation of detecting excrement and a resident's health abnormality.
FIG. 3 is a flowchart showing an example of the operation of the controller 200.

In step S1, the controller 200 (specifically, the data analysis unit 203) receives the gas data transmitted from the wireless device 14 of the home electric appliance 10. Specifically, the data analysis unit 203 receives gas data through the communication unit 202 at least every several tens of seconds. The gas data is stored in the memory in the data analysis unit 203.

In step S2, the controller 200 (specifically, the data analysis unit 203) determines whether or not there is a person in the room. For example, the data analysis unit 203 determines whether or not there is a person in the room based on the detection result received from the motion sensor 201. When a person is detected by the motion sensor 201, that is, when the data analysis unit 203 determines that there is a person in the room (YES in step S2), the process proceeds to step S3.

When the data analysis unit 203 determines that there is no person in the room (NO in step S2), the process proceeds to step S8.

In step S3, the controller 200 (specifically, the data analysis unit 203) uses the gas data (specifically, the first gas component and the second gas included in the gas data) stored in the memory. Component) is analyzed. The data analysis unit 203 detects excrement and resident health abnormalities by analyzing gas data.

When the data analysis unit 203 detects the excrement, the data analysis unit 203 is in units of ppm (parts per million) of the first gas component (ammonia in the present embodiment) among the components contained in the gas data. Analyze the changes in each short period (first period) in. In the present embodiment, the data analysis unit 203 analyzes the change of the first gas component every several tens of seconds. However, in step S3, even if the controller 200 (specifically, the data analysis unit 203) constantly detects the excrement (for example, every few seconds) according to the reception interval of the gas data from the home electric appliance 10. Good.

When the data analysis unit 203 detects a health abnormality, the data analysis unit 203 performs a long-term (second period) in units of ppb (parts per billion) of the second gas component among the components contained in the gas data. ), The average value (second value) of the second gas component in the predetermined period (second period) is calculated.

FIG. 4 is a diagram showing an example of a combination of a second gas component and a disease associated with the second gas component.

In this embodiment, the second gas component is at least one of ammonia, acetone, and nonanal. The data acquisition start timing for calculating the average value of the second component is, for example, when there is no change in the detected value of the second gas component in ppb units in one hour and there is no change in several hours. .. The data acquisition end timing for calculating the average value of the second component is, for example, predetermined when the detected value of the second gas component exceeds a predetermined threshold value in one hour in ppb units or several hours. It is when the threshold is exceeded. In this case, the controller 200 manages the time. Thereby, for example, it is possible to detect a resident's health change every few months.

In step S4, the controller 200 (specifically, the data analysis unit 203) determines whether or not the excrement has been detected. For example, in the controller 200 (specifically, the data analysis unit 203), a value (first value) indicating the amount of ammonia is predetermined in a predetermined period (that is, the first period). Determine if it is greater than the threshold.

In a predetermined period (that is, the first period), when the value indicating the amount of ammonia (first value) is larger than the predetermined threshold value (YES in step S4), the controller 200 excretes. It is determined that an object has been detected, and the process proceeds to step S5.

When the controller 200 does not detect excrement, that is, when the value indicating the amount of ammonia (first value) is equal to or less than the predetermined threshold value in the predetermined period (that is, the first period). (NO in step S4), the controller 200 determines that the excrement has not been detected, and the process proceeds to step S6.

In step S5, the controller 200 (specifically, the data analysis unit 203) stores the notification data to be transmitted to the home electric appliance 10 in the memory.

In step S6, the controller 200 (specifically, the data analysis unit 203) determines whether or not a health abnormality has been detected. For example, the controller 200 determines whether the average value (second value) of the second gas component calculated in step S3 is larger than a predetermined threshold value (for example, the amount of change).

When the average value of the second gas component is larger than the predetermined threshold value (YES in step S6), the controller 200 determines that the health abnormality has been detected, and the process proceeds to step S11.

When the average value of the second gas component is equal to or less than a predetermined threshold value (NO in step S6), the controller 200 determines that the health abnormality has not been detected, and the process proceeds to step S7.

In step S7, the controller 200 (specifically, the data analysis unit 203) stores the gas data (for example, the second value) obtained in step S3 in the memory. As a result, gas data is stored in the controller 200.

In step S8, the controller 200 (specifically, the data analysis unit 203) analyzes the gas data stored in the memory. Specifically, the data analysis unit 203 does not detect excrement, but detects resident health abnormalities. In the present embodiment, the data analysis unit 203 calculates the average value (second value) of the second gas component in the predetermined period (second period).

In step S9, the controller 200 (specifically, the data analysis unit 203) determines whether or not a health abnormality has been detected. For example, the controller 200 determines whether the average value (second value) of the second gas component calculated in step S8 is larger than a predetermined threshold value in the second period. In step S9, the controller 200 may calculate the average value of the second gas component in the first period and determine whether it is larger than a predetermined threshold value.

When the average value (second value) of the second gas component is larger than the predetermined threshold value (YES in step S9), the controller 200 determines that a health abnormality has been detected, and the process proceeds to step S11. Transition.

When the average value (second value) of the second gas component is equal to or less than a predetermined threshold value (NO in step S9), the controller 200 determines that the health abnormality has not been detected, and the process is stepped. Move to S10.

In step S10, the controller 200 (specifically, the data analysis unit 203) stores the gas data (for example, the second value) obtained in step S8 in the memory. As a result, gas data is stored in the controller 200.

In step S11, the controller 200 (specifically, the wireless device 14) transmits data such as human detection data, alarm data, and control data for controlling the home electric appliance 10 detected by the motion sensor 201. It is transmitted to the home electric appliance 10.

After step S11, the process returns to step S1, and the processes from step S1 to step S11 are repeated.

Next, the operation of the home electric appliance 10 (specifically, the control board 11) when the alarming operation is performed will be described.
FIG. 5 is a flowchart showing an example of the operation of the home electric appliance 10 (specifically, the control board 11) when the alarming operation is performed.

In step S21, the control board 11 receives the human detection data and the notification data from the controller 200.

In step S22, the control board 11 determines whether or not there is a person in the room based on the detection data of the person.

When the control board 11 determines that there is a person in the room (YES in step S22), the process proceeds to step S23.

When the control board 11 determines that there is no person in the room (NO in step S22), the process proceeds to step S25.

In step S23, the control board 11 determines whether the home electric appliance 10 is operating. That is, the control board 11 determines whether the home electric appliance 10 is performing a normal operation (an operation other than the fan 13).

The control board 11 controls the fan 13 according to the operating status of the home electric appliance 10. Specifically, when the control board 11 determines that the home electric appliance 10 is operating (YES in step S23), the process proceeds to step S25.

When the control board 11 determines that the home electric appliance 10 is not operating (NO in step S23), the process proceeds to step S24.

In step S24, the control board 11 controls the fan 13 so that the fan 13 is driven at intervals of several minutes.

In step S25, the control board 11 causes the display device 15 to output an alarm signal according to the control signal received from the controller 200. In this case, for example, the display device 15 composed of LEDs (light emitting diodes) blinks. This indicates to those around the home appliance 10 that excrement or health abnormalities have been detected in the room.

Further, the controller 200 transmits an alarm signal to the alarm device 100, and the alarm signal is output from the alarm device 100. As a result, it is possible to notify a person in a remote place from the home electric appliance 10 of the detection of excrement or the detection of a health change. The person who is remote from the home electric appliance 10 is, for example, a caregiver or a nurse who is outside the room where the home electric appliance 10 is installed.

In step S26, the control board 11 acquires the gas data detected by the gas sensor 12 and transmits it to the wireless device 14. The gas data is transmitted from the wireless device 14 to the controller 200 (step S27).

After step S27, the process returns to step S21, and the above process is repeated.

As described above, according to the first embodiment, it is possible to provide the monitoring system 1 capable of monitoring the situation of the resident with a simple configuration.

When the controller 200 detects excrement or a change in the health of the resident, the alarm device 100 outputs at least one of a signal, a voice, and an image. As a result, it is possible to notify the caregiver or the nurse that the excrement or the health change of the resident has been detected.

By using the home electric appliance 10 as a device for detecting gas data, it is possible to detect excrement or resident health abnormalities in daily life with a simple system, and support a caregiver or a nurse. be able to.

Furthermore, in the detection of health abnormalities, changes in gas data over a long period of time are analyzed under predetermined conditions, so that it is possible to detect the initial stage of the resident's illness and manage the physical condition of the resident. It can be done efficiently.

Embodiment 2.
FIG. 6 is a block diagram schematically showing the configuration of the monitoring system 1a according to the second embodiment of the present invention.
The monitoring system 1a according to the second embodiment is different from the monitoring system 1 according to the first embodiment in that it has at least two home appliances 10. In the present embodiment, the types of each home appliance 10 are an air conditioner, an air purifier, a microwave oven, an IHCH (hereinafter referred to as an IH cooking heater), a futon dryer, and a ventilation fan.

In the present embodiment, the plurality of home appliances 10 are home appliances 10 (first) as at least one first device belonging to a group (first group) of home appliances 10 having a short distance from the resident's bed. Home appliances 10a) and home appliances 10 as at least one second device belonging to the group of home appliances 10 (second group) far from the bed (also referred to as second home appliances 10b). It is divided into.

The first home electric appliance 10a and the second home electric appliance 10b have the same components as the home electric appliance 10 described in the first embodiment. The first home electric appliance 10a and the second home electric appliance 10b detect a component of air in the room and transmit gas data indicating the component to the controller 200.

In facilities for the elderly and long-term care facilities, the elderly live on the bed for a long time, so the gas data collected by the first home appliance 10a, which is close to the bed, detects excrement and health abnormalities. Used as data for. As a result, the accuracy of excrement detection can be improved.

On the other hand, the gas data collected by the second home electric appliance 10b, which is far from the bed, is not used as data for detecting excrement, but is used as data for detecting health abnormalities. As a result, the accuracy of detecting health abnormalities can be improved.

Next, the operation of each home electric appliance 10 in the watching system 1a will be described.
FIG. 7 is a flowchart showing an example of the operation of each home electric appliance 10.

In step S31, the control board 11 of each home electric appliance 10 receives human detection data, alarm data, operation data of a plurality of home electric appliances 10, and fan control data for controlling the drive of the fan 13 from the controller 200. To do. The operation data is data indicating the operating state of the home electric appliance 10. The operation data is transmitted from each home electric appliance 10 to the controller 200 at any time.

In step S32, the control board 11 determines whether or not there is a person in the room based on the detection data of the person received from the controller 200.

When the control board 11 determines that there is a person in the room (YES in step S32), the process proceeds to step S33.

When the control board 11 determines that there is no person in the room (NO in step S32), the process proceeds to step S37.

In step S33, the control board 11 uses the operation data received from the controller 200 to determine whether or not the number of home appliances 10 in the stopped state (that is, the state in which the normal operation is stopped) is 0.

When the number of home appliances 10 in the stopped state is 0 (YES in step S33), the process proceeds to step S37.

When the number of home appliances 10 in the stopped state is one or more (NO in step S33), the process proceeds to step S34.

In step S34, the control board 11 uses the operation data to determine whether or not the number of home appliances 10 in the stopped state is one.

When the number of home appliances 10 in the stopped state is one (YES in step S34), the process proceeds to step S35.

When the number of home appliances 10 in the stopped state is two or more (NO in step S34), the process proceeds to step S36.

In step S35, the control board 11 in the home electric appliance 10 in the stopped state controls the fan 13 so that the fan 13 is driven at intervals of several minutes, and acquires gas data.

FIG. 8A is a timing chart of the fan 13 of the first home electric appliance 10a, and FIG. 8B is a timing chart of the fan 13 of the second home electric appliance 10b.

In step S36, the process when all the home electric appliances 10 are in the stopped state will be described. In step S36, the controller 200 controls the fan 13 of the first home electric appliance 10a and the fan 13 of the second home electric appliance 10b according to the arrangement of the first home electric appliance 10a and the second home electric appliance 10b. That is, the processing for each home electric appliance 10 differs depending on the distance from the bed of the home electric appliance 10 in the stopped state. As a result, as shown in FIGS. 8A and 8B, the drive timing and drive time of the fan 13 of the first home electric appliance 10a and the fan 13 of the second home electric appliance 10b are different from each other.

Specifically, in the first home appliance 10a, which is a home appliance 10 that is in a stopped state and is close to the bed, the control board 11 has a fan 13 as described in the first embodiment. The fan 13 is controlled so as to be driven at intervals of several minutes. The distance from the bed to each home appliance 10 is preset in the controller 200.

In this case (step S36), the data analysis unit 203 of the controller 200 determines the ppm of the first gas component (ammonia in the present embodiment) among the components contained in the gas data received from the first home electric appliance 10a. Analyze changes in units. For example, if excrement is detected in 30 minutes, the alarm processing is performed in step S37. On the other hand, if excrement is not detected in the first home electric appliance 10a, the fan 13 of the other home electric appliance 10 in the stopped state (that is, the second home electric appliance 10b far from the bed) is driven. , The controller 200 transmits a drive signal, which is a control signal of the fan 13, to the second home electric appliance 10b.

Further, in step S36, the data analysis unit 203 of the controller 200 excretes the gas data received from the second home electric appliance 10b for, for example, 30 minutes from the start of driving the second home electric appliance 10b (start of driving the fan 13). If no object is detected, the controller 200 stores the average value of the gas data received from the second home electric appliance 10b in the memory.

In step S37, the control board 11 causes the display device 15 to output an alarm signal according to the signal received from the controller 200. In this case, for example, the display device 15 composed of LEDs blinks. This indicates to those around the home appliance 10 that excrement or health abnormalities have been detected in the room. Further, the controller 200 transmits an alarm signal to the alarm device 100, and the alarm signal is output from the alarm device 100. As a result, it is possible to notify a person in a remote place from the home electric appliance 10 of the detection of excrement or the detection of a health change.

After the excrement is detected in step S36, when the fan 13 of the second home electric appliance 10b is driven in step S37, the controller 200 sends a stop signal, which is a control signal for stopping the fan 13, to the second. The fan 13 of the second home electric appliance 10b is stopped by transmitting to the home electric appliance 10b. This makes it possible to prevent the gas data containing the first component collected in the second home electric appliance 10b from being used as data for detecting a health abnormality. Therefore, it is possible to improve the accuracy of detecting health abnormalities based on the gas data collected in the second home electric appliance 10b.

In step S38, the process differs depending on the number of home appliances 10 in the stopped state. Specifically, when the number of home appliances 10 in the stopped state is 0 or 1, the process in step S38 is the same as in step S26 (FIG. 5) described in the first embodiment.

In step S38, when the number of the home appliances 10 in the stopped state is two or more, the controller 200 controls the home appliances 10 according to the type of the home appliances 10. For example, when the home electric appliance 10 is an air conditioner or an air purifier, the controller 200 transmits a control signal for driving the fan 13 to the home electric appliance 10 which is an air conditioner or an air purifier. As a result, in the home electric appliance 10 which is an air conditioner or an air purifier, the fan 13 is driven and gas data is acquired. When the air conditioner or the air purifier is operating normally, it is difficult to control the rotation speed of the fan 13, so that gas data for detecting a health change is not accumulated in the controller 200. That is, the controller 200 (specifically, the data analysis unit 203) changes the handling of gas data according to the operating status of the home electric appliance 10.

When the microwave oven, IH cooking heater, or ventilation fan as the home appliance 10 is operating normally, there is a high possibility that the odor generated by cooking is included in the gas data. It is desirable that no gas data is acquired for product 10.

Further, when the futon dryer as the home electric appliance 10 is operating normally, it is assumed that there is no resident in the bed, so it is desirable that the excrement is not detected. However, since the second gas component contained in the futon is used for detecting a health change, when the controller 200 receives the second gas component contained in the futon, the gas containing the second gas component is used. Data may be stored in memory.

In step S39, each home electric appliance 10 (specifically, the wireless device 14) transmits the operation data indicating its own operating state and the gas data acquired in step S38 to the controller 200.

After step S39, the process returns to step S31, and the above process is repeated.

The watching system 1a according to the second embodiment has the same effect as the watching system 1 according to the first embodiment.

Further, as compared with the monitoring system 1 according to the first embodiment, the monitoring system 1a according to the second embodiment can acquire gas data from a plurality of home electric appliances 10, so that the place where the gas data is collected is biased. Can be reduced, and the accuracy of excrement detection and health abnormality detection can be improved.

Further, the monitoring system 1a according to the second embodiment analyzes (analyzes) gas data according to the distance from the bed of the home electric appliance 10 in the stopped state as compared with the monitoring system 1 according to the first embodiment. Therefore, the accuracy of excrement detection and health abnormality detection can be improved.

Further, the monitoring system 1a according to the second embodiment analyzes (analyzes) gas data according to the type of the home electric appliance 10 as compared with the monitoring system 1 according to the first embodiment, so that excrement can be detected and excrement can be detected. The accuracy of detecting health changes can be improved.

The features of each of the embodiments described above can be combined with each other as appropriate.

1,1a watching system, 10,10a, 10b home appliances, 11 control board, 12 gas sensor, 13 fan, 14 wireless device (communication device), 15 display device, 16 intake port, 100 alarm device, 200 controller, 201 people Motion sensor, 202 communication unit, 203 data analysis unit.

Claims (8)

A monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device.
Further equipped with a second device installed in the room
The first device is
With fans
A gas sensor that detects the components of the air in the room taken in by the fan, and
It has a communication device that transmits gas data indicating the component detected by the gas sensor to the controller.
The controller
A communication unit that receives the gas data from the first device, and
It has a data analysis unit that analyzes the gas data.
The second device detects the component of the air in the room, and transmits the components shown to moth Sudeta to said controller,
The controller transmits a control signal to the first device so that the fan is driven at predetermined intervals.
Watching system. The controller has a motion sensor that detects a person, and has a motion sensor.
The monitoring system according to claim 1, wherein when the person is detected by the motion sensor, the data analysis unit analyzes the gas data. The monitoring system according to claim 1 or 2 , wherein the second device has a fan. It said controller, said first device and in accordance with the arrangement of the second device, the fan and watching system according to claim 3 for controlling the fan of the second device of the first device. A monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device.
Further equipped with a second device installed in the room
The first device is
With fans
A gas sensor that detects the components of the air in the room taken in by the fan, and
A communication device that transmits gas data indicating the component detected by the gas sensor to the controller.
Have,
The controller
A communication unit that receives the gas data from the first device, and
With a data analysis unit that analyzes the gas data
Have,
The second device has a fan, detects a component of air in the room, and transmits gas data indicating the component to the controller.
Said controller in accordance with the arrangement of the first device and the second device, for controlling said fan of the fan and the second device of the first device
Defense system seen. The monitoring system according to any one of claims 1 to 5, further comprising a alarm device that outputs at least one of a signal, a voice, and an image based on the analysis result of the gas data. A monitoring system including a first device installed in a room and a controller installed in the room and communicating with the first device.
Further equipped with a second device installed in the room
The first device is
With fans
A gas sensor that detects the components of the air in the room taken in by the fan, and
A communication device that transmits gas data indicating the component detected by the gas sensor to the controller.
Have,
The controller
A communication unit that receives the gas data from the first device, and
With a data analysis unit that analyzes the gas data
Have,
The second device detects a component of air in the room and transmits gas data indicating the component to the controller.
The first device has a display device and has a display device.
At least one of a signal, a voice, and an image based on the analysis result of the gas data is output from the display device.
Defense system seen. The first device has a control board and has a control board.
The monitoring system according to any one of claims 1 to 7, wherein the control board controls the fan of the first device according to the operating status of the first device.

Images