JP7480977B2 - Remote control module and monitoring system - Google Patents

Description

The present invention relates to a remote control module and a monitoring system.

A system is in operation that monitors the condition of residents from a remote location, detects abnormalities, and protects them. Such systems are described, for example, in Patent Document 1 and Patent Document 2. The monitoring system described in Patent Document 1 is described as determining the safety of residents by using fluctuations in power consumption measured by a meter (Smart Meter (registered trademark)) in the monitored household, as well as the presence or absence of manual operation of a television remote control in the same household. The Smart Meter (registered trademark) is connected to a distribution board installed in the house of the household whose safety is monitored. Furthermore, Patent Document 1 describes that the system is equipped with a battery-powered communication device having a housing that conforms to the AA battery standard, and that an electronic circuit board is stored in an offset portion between the cylindrical center axis of the battery-powered communication device and the cylindrical center axis of the housing. In the safety monitoring system described in Reference 2, an electronic component mounted on the circuit board detects that a manual operation button has been pressed.

Patent document 2 describes that an abnormal indoor temperature signal is detected when the room temperature signal indicates a temperature below 5°C or above 30°C for 60 minutes, and that a heat stroke alert signal is detected when the heat index calculated from the room temperature signal and humidity signal reaches 28°C or above.

JP 2019-106130 A JP 2017-168098 A

In recent years, summer temperatures in Japan have tended to rise compared to previous years, and the use of air conditioning equipment indoors is encouraged to prevent heatstroke. However, installing a device to measure power usage on a distribution board, as in Patent Document 1, requires knowledge of the configuration and specifications of the distribution board, and may give residents the impression that the installation work is complicated. For this reason, the invention described in Patent Document 1 is disadvantageous in promoting a system for monitoring resident activity.

In addition, in a configuration that detects abnormalities by measuring room temperature and humidity as in Patent Document 2, the threshold temperature and duration of the temperature that serve as the threshold for outputting an alert tend to be set relatively high to prevent false alarms. For this reason, it was difficult for the monitoring system described in Patent Document 2 to detect abnormalities in residents at an early stage or to prevent abnormalities before they occur.
The present invention has been made in consideration of the above points, and relates to a monitoring system and a remote control module that are easy to install and suitable for detecting heat stroke early or preventing it before it occurs.

The monitoring system of the present invention includes a remote control module having a device attachment section for attachment to a remote control device having an operation section for remotely operating an appliance, an operation detection section for detecting that the operation section has been operated, and a first communication section for transmitting an operation signal related to the operation detected by the operation detection section, a temperature sensor for detecting an environmental temperature and outputting an environmental temperature signal related to the detected environmental temperature, a second communication section for receiving the operation signal and the environmental temperature signal, a state estimation section for estimating the state of a resident residing in the building in which the appliance is placed based on the operation signal and the environmental temperature signal received by the second communication section, and a state output section for outputting a state signal according to the estimation result of the state estimation section.

The remote control module of the present invention includes a device mounting section for mounting on the outer surface of a remote control device having an operation section for remotely operating an appliance, an operation detection section for detecting that the operation section has been operated, and a first communication section for transmitting an operation signal related to the operation detected by the operation detection section.

The present invention can provide a monitoring system and a remote control module that are easy to install and are ideal for early detection of heat stroke or for preventing it before it occurs.

1 is a schematic diagram for explaining a monitoring system according to one embodiment of the present invention; FIG. 2 is a perspective view for explaining the remote control module shown in FIG. 1 . 3A is a front view of the remote control module shown in FIG. 2, FIG. 3B is a bottom view of the remote control module, and FIG. 3C is a side view of the remote control module. 1A and 1B are diagrams for explaining how to attach a remote control module to a remote control device. 2 is a functional block diagram for explaining a remote control module shown in FIG. 1 . FIG. 2 is a functional block diagram for explaining the power monitoring module shown in FIG. 1 . FIG. 2 is a functional block diagram for explaining a state management module shown in FIG. 1 . 2 is a flowchart for explaining a process performed in an MPU of a state management module shown in FIG. 1 .

One embodiment of the present invention will be described below. In this embodiment, the same components are given the same reference numerals, and some of the description will be omitted. In addition, this embodiment and the drawings used in this embodiment are merely examples of the configuration of the present invention, and do not limit the specific configuration, shape, dimensions, arrangement, etc.

Figure 1 is a schematic diagram for explaining a monitoring system 100 of this embodiment. The monitoring system 100 comprises a remote control module 3 that is attached to a remote control device 2 for use, a status management module 5, and a temperature sensor. In this embodiment, as described below, the temperature sensor is a temperature and humidity sensor 74 (Figure 4) that measures humidity as well as temperature, and is provided in the power monitoring module 7. In this embodiment, the air conditioning device 1, the remote control device 2, the remote control module 3, the status management module 5, and the power monitoring module 7 are all located in the same room of a building. Hereinafter, the term "environment" in this embodiment refers to this "room."

The monitoring system 100 shown in FIG. 1 further includes a power monitoring module 7, a router 8, and an alarm device 9. The power monitoring module 7 manages the power consumed by the air conditioning device 1. The router 8 communicates with the server of the monitoring system 100 via cloud C. Such a router 8 can be, for example, a wireless LAN router for providing NetMill (registered trademark) services.

The remote control device 2 may be any device that includes an operation unit 21 for remotely operating an appliance, and in this embodiment, it operates an air conditioner 1 that adjusts the room temperature and humidity of the air in the room.
The operation section 21 of the remote control device 2 is a device for sending instruction signals _s3 to instruct the air conditioning equipment 1 to perform operations such as cooling, heating, dehumidification, etc. The operation section 21 is provided with a plurality of buttons corresponding to such instructions. The remote control device 2 further includes a display screen 22, which enables the operator of the remote control device 2 to visually confirm the operations instructed to the air conditioning equipment 1.

The remote control module 3 detects that the operation unit 21 of the remote control device 2 has been operated, and outputs an operation signal _s1 indicating that the operation has been performed to the status management module 5. The status management module 5 receives the operation signal _s1 . The status management module 5 also receives a power/temperature signal _s4 from the power monitoring module 7. The status management module 5 estimates the status of the resident residing in the room in which the air conditioner 1 and the like are placed based on the operation signal s1 and the power/temperature signal _s4 . Then, the status management module 5 transmits a status signal _s2 according to the result of the estimation. The status signal _s2 may be transmitted to a warning device 9. The warning device 9 may be provided either inside or outside the room. Furthermore, the status signal _s2 may be transmitted to the cloud C via a router 8.

The above "residents" are not limited to those who make the facility their home, but also include those who work at the facility, and those who temporarily reside at the facility, such as those who visit or drop in at the facility. Furthermore, the above transmission or reception is not limited to a configuration in which signals are sent and received wirelessly or via wire between separate components located at a distance from each other, but also includes signals sent and received between components installed within the same device.

The operation signal _s1 , the status signal _s2 , the instruction signal _s3 , and the power/temperature signal _s4 may all be transmitted and received by wire or wirelessly, but in the case of wireless communication, it is preferable that the operation signal _s1 and the power/temperature signal _s4 are transmitted and received by Bluetooth (registered trademark). Furthermore, the status signal _s2 may be transmitted by using a contact notification in which a relay (not shown) is provided in the status management module 5 and a relay contact is turned on.

Next, the above configuration will be described in more detail.
(Remote control module)
Fig. 2 is a perspective view for explaining the remote control module 3. Fig. 3(a) is a front view of the remote control module 3 shown in Fig. 2, Fig. 3(b) is a bottom view of the remote control module 3, and Fig. 3(c) is a side view of the remote control module 3. Fig. 4 is a diagram for explaining the attachment of the remote control module 3 to the remote control device 2.

2 and 4, the remote control module 3 includes a device mounting section 33 which is a device mounting section for mounting on the outer surface of the remote control device 2 having an operation section 21 for remotely operating the air conditioning appliance 1, a remote control connection section 35, and a detection circuit 37 which is an operation detection section that detects operation of the operation section 21. The remote control module 3 also includes a wireless communication section 36 which is a first communication section that transmits an operation signal _s1 related to the operation detected by the detection circuit 37.
In this way, in this embodiment, the remote control module 3 is attached to the outer surface of the remote control device 2, which allows for greater freedom in designing the size and shape of the remote control module 3 than if the remote control module 3 were provided inside the remote control device 2.

The remote control module 3 is attached to the remote control device 2 so that it is in contact with the back surface opposite the surface on which the display screen 22 is located. As shown in Figures 2 and 3(a) to 3(c), the remote control module 3 has a cover 30 that has a rectangular base 32 when viewed from the front and a box 31 provided on the surface 30a of the base 32. The two long sides of the base 32 continue to the side surface 30c, and the end of the side surface 30c is curved in the x direction of the x, y, z coordinate system shown in the figures. This configuration forms the device mounting section 33.

According to the cover 30, a space S is formed on the back surface 30b side, surrounded on two sides by the device mounting portion 33. In this embodiment, the remote control device 2 can be inserted into the space S so as to slide, and the remote control module 3 can be attached to the remote control device 2.
The box 31 is a housing having a base 32 as a bottom surface, and inside the housing, a control unit for controlling the remote control module 3 is housed. The control unit is composed of electronic components and a circuit board on which the electronic components are mounted, and the electronic components are electrically connected to each other by wiring and terminals formed on the circuit board.

3(b) and 4, a remote control connector 35 is provided on the rear surface 30b of the remote control module 3. The remote control connector 35 is a conductive terminal exposed on the rear surface 30b from inside the box 31. In this embodiment, the cover (not shown) of the battery box 25 that houses the battery of the remote control device 2 is opened, and the remote control module 3 is attached so that the remote control connector 35 comes into contact with a conductor in the battery box. The conductor in the battery box is, for example, a spring that comes into contact with the terminal of a dry battery.
In this embodiment, if necessary, a dedicated remote control device 2 to which the remote control connecting unit 35 can be attached may be provided together with the remote control connecting unit 35. In addition, in this embodiment, the remote control connecting unit 35 may be configured to have a shape that allows it to be attached to the remote control device 2 in a general purpose manner.
In this embodiment, the battery box 39 is designed to be larger than the battery box of the remote control device 2, and a dry cell with a larger capacity can be used.

Figure 5 is a functional block diagram for explaining the circuits housed in the box 31. As shown in Figure 5, the remote control module 3 has a detection circuit 37, which is an operation detection unit that detects that the operation unit 21 has been operated, and a wireless communication unit 36, which is a first communication unit that transmits an operation signal related to the operation detected by the detection circuit 37. The remote control module 3 also has an MPU (Micro Processing Unit) 38 that provides overall control of this configuration.

The remote control module 3 also has a battery box 39 which is a battery housing section for housing a battery. The remote control device 2 operates by receiving power from a battery (not shown) housed in the battery box 39. The battery power is supplied to a circuit (not shown) which outputs an instruction signal _s3 of the remote control device 2 via the remote control connector 35.
The battery housed in the battery box 39 also supplies power to the detection circuit 37 , the wireless communication unit 36 and the MPU 38 on the remote control module 3 side.

The detection circuit 37 detects that the operation unit 21 has been operated by using power from the battery housed in the battery box 39. Such a configuration can be realized by providing the detection circuit 37 between the battery box 39 and the remote control connector 35 and observing the current supplied to the remote control device 2 in the wiring that supplies power. The detection circuit 37 detects the current flowing between the battery box 39 and the remote control connector 35 and outputs a signal _s5 to the MPU 38.

In the case where the power supplied to the remote control device 2 is consumed by a plurality of electronic components on the side of the remote control device 2, a threshold value may be set in advance for the detection current of the detection circuit 37, and when a current equal to or greater than the threshold value is detected, the detection circuit 37 may output a detection signal to the MPU 38. The threshold value may be determined, for example, based on the power obtained by adding the power used for outputting the instruction signal _s3 to the power constantly used by the remote control device 2.

The signal _s5 is a constant signal regardless of the type of instruction given to the air conditioning appliance 1, and the MPU 38 detects that the remote control device 2 has been operated by the signal _s5 . When the MPU 38 receives the signal _s5 , it outputs a signal _s6 to the wireless communication unit 36. The wireless communication unit 36 outputs an operation signal _s1 in response to the input of the signal _s6 . The operation signal _s1 is received by the status management module 5. The status management module 5 receives the power/temperature signal _s4 transmitted from the power monitoring module 7 together with the operation signal _s1 transmitted by the remote control module 3.

(Power monitoring module)
6 is a functional block diagram for explaining the power monitoring module 7. The power monitoring module 7 includes a power measuring unit 71 that measures the power supplied from the power plug 62 to the AC outlet 61 of the air conditioner 1, and a voltage control unit 72 that controls the supplied power. The voltage control unit 72 controls the voltage according to the power supplied to the air conditioner 1, preventing a large current from flowing through the air conditioner 1. The power measuring unit 71 is a measurement circuit that measures the power used by the air conditioner 1.

The monitoring system 100 also includes a temperature sensor that detects the environmental temperature and outputs a temperature signal related to the detected temperature. In this embodiment, the temperature sensor is a temperature/humidity sensor 74 that can measure humidity as well as temperature, and this is provided inside the power monitoring module 7. The environmental temperature refers to the temperature in a room where the air conditioning device 1, the remote control device 2, the status management module 5, etc. are placed.
In this embodiment, the temperature and humidity sensor 74 is provided relatively close to the air conditioner 1, making it possible to accurately determine the effect of adjusting the temperature in the room by the air conditioner 1. Furthermore, since the temperature in the upper part of a room is generally higher than the temperature in the lower part, this embodiment makes it possible to detect early on an increase in the environmental temperature on the floor where the occupants are located.

Furthermore, the power monitoring module 7 includes a wireless communication unit 75. The wireless communication unit 75 is configured to transmit a power/temperature signal _s4 indicating the amount of power consumption measured by the power measurement unit 71 and the temperature and humidity measured by the temperature/humidity sensor 74 to the status management module 5. The MPU 73 may periodically acquire the output signals of the power measurement unit 71 and the temperature/humidity sensor 74, and transmit the power/temperature signal _s4 at regular intervals.

(State Management Module)
7 is a functional block diagram for explaining the state management module 5. The state management module 5 includes a wireless communication unit 52 which is a second communication unit that receives an operation signal _s1 and a power/temperature signal _s4 . The state management module 5 also includes an MPU 55 which is a state estimation unit that estimates the state of the resident living in the building in which the air conditioner 1 is placed based on the operation signal _s1 and the power/temperature signal _s4 received by the wireless communication unit 52, and a contact control unit 53 which is a state output unit that outputs a state signal _s2 according to the estimation result of the MPU 55.
The contact control unit 53 may be a relay remote controller that turns on and off the relay of the router 8 by remote control.

The MPU 55 estimates the state of the resident by combining the timing at which the wireless communication unit 52 received the operation signal _s1 with the environmental temperature indicated by the power and temperature signal _s4 . In this embodiment, the input of the operation signal s1 _determines that the resident is active, and the absence of the operation signal s1 _for a certain period of time (the absence of operation of the remote control device 2) is considered as one of the conditions for determining that an abnormality may occur in the resident.
Furthermore, in this embodiment, the temperature measured by the temperature/humidity sensor 74 is determined from the power/temperature signal _s4 , and the temperature reaching a temperature that is considered to be uncomfortable for the occupants is considered to be one of the conditions for determining that an abnormality may occur in the occupants.

Furthermore, in this embodiment, as described above, the power monitoring module 7 includes the power measurement unit 71 which is a power usage measurement unit. The MPU 55 can also estimate the state of the occupant by combining the reception timing of the operation signal _s1 , the environmental temperature indicated by the power/temperature signal _s4 , and the power usage measured by the power measurement unit 71. Such an estimation is performed, for example, by determining that an abnormality has occurred when the power used in the air conditioner 1 is too low or zero. A situation in which the power consumption of the air conditioner 1 is low or zero even though the occupant is operating the remote control device 2 occurs, for example, when the remote control device 2 is operated while the air conditioner 1 is off, when the occupant is not operating the air conditioner 1 as intended (the air conditioner 1 is set to heating despite the intention of cooling), or when the set temperature of the air conditioner 1 is too high.

The above estimation by the MPU 55 is performed using estimation conditions such as preset thresholds. The estimation conditions may be provided to the MPU 55 by connecting a serial console terminal to the setting connector 54, for example. Possible estimation conditions include, for example, a threshold temperature, a threshold power usage, a date and time, a threshold time interval (threshold time interval) for operating the remote control device 2, and alarm conditions determined by combining multiple such conditions. Also, the threshold temperature may be set to different values in summer and winter.

The time interval during which the remote control device 2 is operated is equal to the time interval during which the operation signal _s1 is received by the wireless communication unit 52 of the status management module 5. The MPU 55 counts the time interval during which the operation signal _s1 is received and compares the time interval with a set threshold time interval. If the reception time interval is shorter than the threshold time interval, the MPU 55 determines that the resident is normally active. On the other hand, if the reception time interval reaches the threshold time interval, the MPU 55 determines that the resident is inactive.

In this embodiment, the MPU 55 estimates the state of the resident by combining the time interval and a comparison result of comparing the environmental temperature included in the power/temperature signal _s4 received by the wireless communication unit 52 with a predetermined threshold temperature. Here, the threshold temperature is selected from temperatures outside the range of temperatures generally considered to be preferable for humans. In this embodiment, if the state of activity of the resident is determined to be inactive based on the time interval and the environmental temperature is equal to or higher than the threshold temperature or lower than the threshold temperature, it is determined that there is a possibility that an abnormality will occur in the resident.

However, in this embodiment, the reception timing is not limited to the time interval at which the operation signal is received as described above. The reception timing may be determined by the time of day. When judging the activity status of the resident based on the reception time of the operation signal, for example, it is possible to judge that there is a possibility that something abnormal will occur to the resident if the remote control device 2 is not operated even after a pre-set time (e.g. 11:00) at which the temperature starts to rise has passed. It is also possible to associate the reception timing with the outside air temperature and judge that there is a possibility that something abnormal will occur to the resident if an operation signal is not received for more than one hour even after the outside air temperature reaches 30°C or higher.

In addition, in this embodiment, the reception time of the operation signal _s1 may be recorded for a plurality of days. In such a case, the MPU 55 may determine that there is a possibility that something is wrong with the resident because the remote control device 2 has not been operated even after the time when the operation signal _s1 was received in the past.

The status management module 5 also includes a calendar management unit (RTC: Real-Time Clock) 58 that changes the threshold temperature compared with the environmental temperature depending on the month or time when the environmental temperature is detected. The calendar management unit 58 is a device that automatically counts years, months, and days starting from the date and time set in the MPU 55. In this embodiment, for example, the threshold temperatures may be set to different temperatures for summer and winter, and the threshold temperature according to the current date and time determined by the calendar management unit 58 may be compared with the environmental temperature.

The calendar management unit 58 receives power from a battery 59 to prevent the date and time count from stopping due to a power outage. The status management module 5 further includes a recovery button 57 and a temperature and humidity sensor 56. The recovery button 57 is a button for resetting and restarting the status management module 5. The temperature and humidity sensor 56 is a sensor that measures the temperature and humidity inside the status management module 5. The temperature and humidity sensor 56 can measure the environmental temperature below the air conditioning device 1. There may be a difference in the environmental temperature between above and below. Taking this into consideration, in this embodiment, the average value of the temperature and humidity sensor 74 of the power monitoring module 7 and the temperature and humidity sensor 56 may be compared with the threshold temperature.

When different threshold temperatures are set for summer and winter, for example, the threshold temperature for summer may be set to 28° C., and monitoring of the timing of receiving the operation signal s ₁ may be started when the environmental temperature becomes 28° C. or higher. Also, for example, the threshold temperature for winter may be set to 5° C., and monitoring of the timing of receiving the operation signal s 1 may be started when the environmental temperature becomes less than 5° C. By setting the threshold temperature for summer relatively low, heat stroke can be prevented, and by setting it high, the occurrence of false alarms can be suppressed. In order to detect the risk of heat stroke early and suppress the occurrence of false alarms, in this embodiment, for example, when the threshold temperature is set relatively low, the threshold of the time interval of the operation is set relatively long, or when the threshold temperature is set relatively high, the threshold of the time interval of the operation is set relatively short.

The status management module 5 also includes a power supply control unit 51 that turns the power supply of the power monitoring module 7 on or off based on information related to power usage contained in the power/temperature signal s _4. The power supply control unit 51 may, for example, output via the wireless communication unit 52 a power supply control signal s ₇ that turns on the air conditioning device 1 when the power used by the air conditioning device 1 is smaller than a specified value.
In this way, in the present embodiment, when the power consumption of the air conditioning equipment 1 is low in the summer and the ambient temperature has risen above the threshold temperature, the air conditioning equipment 1 is operated, and excessive increases in the ambient temperature can be prevented without the resident having to operate it.

(Warning device)
The monitoring system 100 also includes a warning device 9 that outputs at least one of characters, light, sound, and voice to the outside of the building or to the occupants in response to the status signal _s2 . The warning device 9 may be any device that is activated by the status signal _s2 output from the contact control unit 53 and outputs at least one of characters, light, sound, and voice as an alarm. Examples of devices that output characters include an electronic bulletin board and a display screen. Examples of devices that generate light include lamps. Examples of devices that generate sound include buzzers, and examples of devices that generate voice include speakers. The warning device 9 may also output both light and sound. As for sounds, sounds that attract people's attention, such as buzzers and warning sounds, are preferable.
The warning device 9 may output at least one of characters, light, sound, and voice to the outside of the building, or to the resident. When the warning device 9 outputs voice, it may output a voice requesting help such as "Something may be wrong with the resident" to the outside of the building. The warning device 9 may also output a voice giving instructions to the resident such as "The room temperature has exceeded 28°C, please lower the temperature setting of the air conditioner."

(router)
In addition, in this embodiment, the status signal _s2 may be output to the router 8 in addition to the warning device 9 to notify the resident of the status. A specific method of notification may be, for example, sending an email to a ward or municipal institution, or to a pre-defined contact such as a hospital or family member.

(motion)
Next, the operation of the monitoring system 100 of the present embodiment described above will be described.
FIG. 8 is a flow chart for explaining the process performed by the MPU 55 of the state management module 5. Note that FIG. 8 illustrates a process for preventing heatstroke of residents in the summer. When the monitoring system 100 is turned on, the MPU 55 detects the current date from the calendar management unit 58 and sets the threshold temperature t _th . Then, it is determined whether the environmental temperature included in the power/temperature signal s ₄ is equal to or higher than the threshold temperature t _th (step S801). If the environmental temperature is equal to or higher than the threshold temperature t _th (step S801: Yes), the MPU 55 detects the difference (time interval) between the time when the remote control device 2 was operated immediately before and the time when the remote control device 2 was operated the previous time by the operation signal s _1. Note that, in this process, the MPU 55 repeatedly records the time when the operation signal s ₁ was received in a memory (not shown).

Then, the MPU 55 compares the time interval with a preset threshold time interval t _in and judges whether the time interval is equal to or greater than the threshold time interval t _in (step S802). If the operation time interval is equal to or greater than the threshold time interval t _in (step S802: Yes), in this embodiment, it is judged whether the remote control device 2 has stopped being operated despite having been operated (step S803). This judgment may be made, for example, by determining that the remote control device 2 has been operated in the morning of that day as "the remote control device 2 has been operated." This judgment may also be made by determining that the remote control device 2 has been operated before the environmental temperature reaches the threshold temperature t _th .

Then, if the measured time interval exceeds the threshold time interval t _in even though the remote control device 2 is being operated, the MPU 55 may output a status signal _s2 from the contact control unit 53 to cause the warning device 9 or the router 8 to output an alarm to the resident notifying them that a possible abnormality has occurred (step S804).
According to the process of step 803, this embodiment can prevent an alarm from being generated when the resident is absent from the building, the remote control device 2 is not operated, and the environmental temperature rises.

As described above, this embodiment can estimate the state of the occupant based on the operation signal s1 related to the operation of the remote control device for remotely operating the air conditioning equipment ₁ and the temperature measured by the temperature/humidity sensor 74. Therefore, this embodiment can provide a monitoring system 100 that is easy to install because it does not require the installation of a device on a distribution board or the like. Furthermore, this embodiment detects the operation of the remote control device 2 along with the temperature, so there is a low possibility of generating a false alarm, and the environmental temperature when detecting an abnormality can be set low. Therefore, this embodiment can detect abnormalities such as heat stroke early or before they occur.

Note that this embodiment is not limited to the embodiment described above. For example, the temperature sensor is not limited to being provided in the status management module 5 or the power monitoring module 7, but may be built into the remote control module 3. Furthermore, the remote control module 3 of this embodiment is not limited to being attached to a remote control device that operates the air conditioning device 1, but may be attached to a remote control device that operates a television or lighting device.

Furthermore, as described above, in this embodiment, the status signal _s2 is output when it is detected that the operation interval is equal to or greater than the threshold time interval. However, in this embodiment, the status management module 5 may transmit the status signal _s2 at all times and stop the status signal _s2 when the operation signal _s1 is no longer received. In such a configuration, the router 8 and the warning device 9 output an alarm when the status signal _s2 stops.

The above embodiment encompasses the following technical ideas.
(1) A monitoring system including: a remote control module having a device attachment portion for attachment to a remote control device having an operation portion for remotely operating an appliance; an operation detection portion for detecting that the operation portion has been operated; and a first communication portion for transmitting an operation signal related to the operation detected by the operation detection portion; a temperature sensor for detecting an environmental temperature and outputting an environmental temperature signal related to the detected environmental temperature; a second communication portion for receiving the operation signal and the environmental temperature signal; a state estimation portion for estimating a state of a resident residing in a building in which the appliance is placed based on the operation signal and the environmental temperature signal received by the second communication portion; and a state output portion for outputting a state signal according to the estimation result of the state estimation portion.
(2) The monitoring system of (1), wherein the state estimation unit estimates the state of the resident by combining the reception timing at which the second communication unit receives the operation signal and the environmental temperature indicated by the environmental temperature signal.
(3) A monitoring system according to (2), wherein the state estimation unit estimates the state of the resident by combining the time interval during which the second communication unit receives the operation signal and a comparison result between the environmental temperature and a predetermined threshold temperature.
(4) The device further includes a power consumption measurement unit that measures the power consumed by the device,
A monitoring system according to (2) or (3), wherein the state estimation unit estimates the state of the resident by combining the power measured by the power usage measuring unit together with the timing of receiving the operation signal and the environmental temperature indicated by the environmental temperature signal.
(5) Any one of (3) or (4) in the monitoring system, further comprising a calendar management unit that changes the threshold temperature to be compared with the environmental temperature depending on the month or time when the environmental temperature is detected.
(6) A monitoring system according to any one of (1) to (5), wherein the remote control module is provided with a battery storage section for storing a battery, and the operation detection section detects that the operation section has been operated by using power from a battery stored in the battery storage section.
(7) Any one of the monitoring systems (1) to (6), further comprising an alarm device that outputs at least one of text, light, sound, and voice to the outside of the building or to the occupant in response to the status signal.
(8) A device mounting section for mounting on an outer surface of a remote control device having an operation section for remotely operating a device, and an operation detection section for detecting that the operation section is operated;
a first communication unit that transmits an operation signal related to the operation detected by the operation detection unit.

1...Air conditioning equipment 2...Remote control device 3...Remote control module 5...Status management module 7...Power monitoring module 8...Router 9...Warning device 21...Operation unit 22...Display screen 25...Battery box 30...Cover 30a...Front surface 30b...Back surface 30c...Side surface 31...Box 32...Base 33...Device mounting unit 35...Remote control connection unit 36, 52, 75...Wireless communication unit 37...Detection circuit 39...Battery box 51...Power supply control unit 53...Contact control unit 54...Setting connector 56, 74...Temperature and humidity sensor 57...Recovery button 58...Calendar management unit 59...Battery 61...AC outlet 62...Power plug 71...Power measurement unit 72...Voltage control unit 100...Monitoring system

Claims (5)

a remote control module having a device attachment section for attachment to a remote control device having an operation section for remotely operating an air conditioning device, an operation detection section for detecting that the operation section has been operated, and a first communication section for transmitting an operation signal related to the operation detected by the operation detection section;
a temperature sensor that detects an environmental temperature and outputs an environmental temperature signal related to the detected environmental temperature;
a second communication unit that receives the operation signal and the environmental temperature signal; a state estimation unit that estimates a state of a resident living in a building in which the air conditioning device is placed, based on the operation signal and the environmental temperature signal received by the second communication unit; and a state output unit that outputs a state signal according to a result of the estimation by the state estimation unit.
Including,
the state estimation unit estimates a state of the occupant by combining a time interval at which the second communication unit receives the operation signal and a comparison result of comparing an environmental temperature indicated by the environmental temperature signal with a predetermined threshold temperature; and
The estimation process in which the state estimation unit estimates the state of the occupant includes:
a first step of determining whether the environmental temperature is equal to or greater than the threshold temperature;
a second step of determining whether the time interval is equal to or greater than a predetermined threshold time interval;
a third step of determining whether the operation signal has been received during a predetermined period of time that is the same day and a time period prior to the first step in which it has been determined that the environmental temperature has reached or exceeded the threshold temperature;
Including,
the time interval is a time difference between a time when a most recent operation signal was received among the operation signals received before the timing at which the state estimation unit determined in the first step that the environmental temperature is equal to or higher than the threshold temperature, and a time when the operation signal immediately before the most recent operation signal was received;
The state estimation unit is
In the estimation process,
selectively executing the second step when it is determined in the first step that the environmental temperature is equal to or higher than the threshold temperature;
Optionally, when it is determined in the second step that the time interval is equal to or greater than the threshold time interval, the third step is executed;
A monitoring system that selectively estimates that an abnormality caused by the environmental temperature may have occurred to the resident if it is determined in the third step that the operation signal has been received during the specified period. Further comprising a power consumption measurement unit that measures the power consumed by the air conditioning device,
The monitoring system of claim 1 , wherein the state estimation unit estimates the state of the resident by combining the power measured by the power usage measurement unit together with the timing of receiving the operation signal and the environmental temperature indicated by the environmental temperature signal. The monitoring system according to claim 1 or 2, further comprising a calendar management unit that changes the threshold temperature to be compared with the environmental temperature depending on the month or time when the environmental temperature is detected. The monitoring system according to any one of claims 1 to 3, wherein the remote control module includes a battery housing section that houses a battery, and the operation detection section detects that the operation section has been operated by using power from a battery housed in the battery housing section. The monitoring system according to any one of claims 1 to 4, further comprising an alarm device that outputs at least one of text, light, sound, and voice to the outside of the building or to the occupant in response to the status signal.

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