JP6770877B2 - Bathroom anomaly detection system - Google Patents

Description

The techniques disclosed herein relate to bathroom anomaly detection systems.

Patent Document 1 discloses a bathroom monitoring device that detects an abnormality of a bather who is bathing in a bathtub. The bathroom monitoring device of Patent Document 1 includes a sensor that detects the movement of the bather, a timer that measures the time that the bather is in the bathtub, and a control device. The control device detects that an abnormality has occurred in the bather when the time measured by the timer is a predetermined time or longer.

Japanese Unexamined Patent Publication No. 2004-185150

In the bathroom monitoring device of Patent Document 1, when an abnormality of a bather is detected, an alarm is output from a speaker outside the bathroom. In this case, for example, if a resident of a house other than the bather (hereinafter referred to as a cohabitant) is out, the cohabitant cannot notice the alarm output from the speaker. If an abnormality occurs in the bather, prompt and appropriate measures should be taken. Therefore, it is desired to be able to notify the cohabitant that the abnormality of the bather has been detected even when the cohabitant is out.

The present specification proposes a technique capable of increasing the possibility that an appropriate treatment is given to a bather when an abnormality of the bather is detected in the abnormality detection system of the bathroom.

The bathroom abnormality detection system disclosed in the present specification includes a bathroom air conditioner, a management device that can be connected to an external network and can communicate with a terminal device via the external network, and a bather in the bathtub. It is equipped with a human body detection sensor that detects the presence of a bather in some cases, a control device that can communicate with the management device, and a remote control that is arranged in the bathroom and can communicate with the control device. The bathroom air conditioner includes a blower unit that blows air into the bathroom and a wind direction adjustment unit that can adjust the wind direction of the blower unit. The control device determines whether or not there is a bather in the bathtub based on the information detected by the human body detection sensor, and measures the bathing time, which is the time the bather is in the bathtub. Further, when the bathing time of the bather is equal to or longer than the first predetermined time, the control device transmits a first abnormality signal indicating an abnormality of the bather to the management device. When the management device receives the first abnormality signal, it transmits a second abnormality signal indicating the abnormality of the bather to the terminal device via the external network. Further, when the control device determines that the bathing time is equal to or longer than the second predetermined time, the control device transmits the first control signal to the remote controller , and the predetermined time after transmitting the first control signal to the remote controller. By the time the elapse has passed, when the first remote control signal for the first control signal is not received from the remote controller , the wind direction adjusting unit is operated so that the wind blown from the blower unit hits the bather, and the blower unit operates the bather. Blow towards.

According to the above configuration, the control device transmits a first abnormality signal indicating an abnormality of the bather to the management device when the bathing time of the bather is equal to or longer than the first predetermined time. Then, when the management device receives the first abnormal signal, it transmits a second abnormal signal indicating the abnormality of the bather to the terminal device. Even when a resident of a house with an anomaly detection system in the bathroom goes out, there is a high possibility that the terminal device is carried with him. Therefore, for example, even when a resident of a house in which an abnormality detection system for a bathroom is installed is out, it is possible to notify that an abnormality of a bather has been detected. As a result, it is possible to increase the possibility that the bather will be treated promptly and appropriately. In addition, if you take a bath for a long time, you are more likely to fall into an abnormality such as a rash. As a coping method for abnormalities that occur during bathing, it is effective to blow air toward the bather. According to the above configuration, when it is determined that the bathing time is equal to or longer than the second predetermined time, the wind is blown toward the bather. As a result, it is possible to prevent the bather from falling into an abnormal state.

It is a figure which shows the schematic structure of the bathroom air-conditioning system of an Example. It is a figure which shows the schematic structure of the heat source machine of an Example. It is a figure which shows the schematic structure of the bathroom air conditioner of an Example. It is a figure which shows the main structure of the control system of the bathroom air-conditioning system of an Example. It is a flowchart of abnormality detection processing executed by the bathroom air-conditioning system of an Example.

The main features of the examples described below are listed. It should be noted that the technical elements described below are independent technical elements and exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Absent.

The bathroom abnormality detection system disclosed in the present specification includes a bathroom air conditioner, a management device that can be connected to an external network and can communicate with a terminal device via the external network, and a bather in the bathtub. It is equipped with a human body detection sensor that detects the presence of a bather in some cases, a control device that can communicate with the management device, and a remote control that is arranged in the bathroom and can communicate with the control device . The bathroom air conditioner includes a blower unit that blows air into the bathroom and a wind direction adjustment unit that can adjust the wind direction of the blower unit. The control device determines whether or not there is a bather in the bathtub based on the information detected by the human body detection sensor, and measures the bathing time, which is the time the bather is in the bathtub. When it is determined that the bathing time is equal to or longer than the third predetermined time, the control device transmits a third abnormal signal to the remote controller, and receives a second remote controller signal for the third abnormal signal from the remote controller. When the bathing time of the bather is equal to or longer than the first predetermined time, the first abnormality signal indicating the abnormality of the bather is transmitted to the management device. When the management device receives the first abnormality signal, it transmits a second abnormality signal indicating the abnormality of the bather to the terminal device via the external network. When it is determined that the bathing time is longer than the second predetermined time, the control device operates the wind direction adjusting unit so that the wind blown from the blower hits the bather, and the blower toward the bather. Blow.

According to the above configuration, the control device transmits a first abnormality signal indicating an abnormality of the bather to the management device when the bathing time of the bather is equal to or longer than the first predetermined time. Then, when the management device receives the first abnormal signal, it transmits a second abnormal signal indicating the abnormality of the bather to the terminal device. Even when a resident of a house with an anomaly detection system in the bathroom goes out, there is a high possibility that the terminal device is carried with him. Therefore, for example, even when a resident of a house in which an abnormality detection system for a bathroom is installed is out, it is possible to notify that an abnormality of a bather has been detected. As a result, it is possible to increase the possibility that the bather will be treated promptly and appropriately. In addition, if you take a bath for a long time, you are more likely to fall into an abnormality such as a rash. As a coping method for abnormalities that occur during bathing, it is effective to blow air toward the bather. According to the above configuration, when it is determined that the bathing time is equal to or longer than the second predetermined time, the wind is blown toward the bather. As a result, it is possible to prevent the bather from falling into an abnormal state. Further , according to the above configuration, when it is determined that the bathing time is equal to or longer than the third predetermined time, a third abnormal signal is transmitted to the remote controller. In this case, the remote controller can be used to notify that the bather may fall into an abnormal state. Thereby, for example, before the bather falls into an abnormal state, the bather can be encouraged to take an action such as leaving the bathtub. As a result, it is possible to prevent the bather from falling into an abnormal state.

(Feature 1 ) The human body detection sensor may be provided in the bathroom air conditioner.

According to the above configuration, it is possible to simplify the configuration of equipment other than the bathroom air conditioner included in the bathroom air conditioner system.

(Feature 2 ) The management device transmits the second abnormal signal to the terminal device via the external network, and then receives the first response signal to the second abnormal signal from the terminal device via the external network. In some cases, a second response signal to the first abnormal signal may be transmitted to the control device. Further, the control device may measure the elapsed time since the first abnormal signal is transmitted to the management device. In this case, when the control device determines that the second response signal has not been received from the management device by the time when the elapsed time elapses the fourth predetermined time, the control device again informs the management device of the first abnormality. It is good to send a signal.

If the management device has not received the first response signal from the terminal device, the management device does not transmit the second response signal to the control device. In this case, it is highly possible that the residents of the house other than the bather are unaware that they have received the second abnormal signal. Therefore, it is highly possible that appropriate measures have not been taken for bathers. When the control device transmits the first abnormality signal to the management device again, the second abnormality signal is transmitted from the management device to the terminal device again. Therefore, it is possible to urge the bather to take appropriate measures against the abnormality again. This can increase the possibility that appropriate treatment will be given to the bather.

The bathroom air-conditioning system 1 according to the embodiment will be described. As shown in FIG. 1, the bathroom air conditioner system 1 includes a heat source unit 2, a bathroom air conditioner 4, and a bathroom remote controller 6. The bathroom air conditioner 4 is installed on the ceiling of the bathroom 8 of the house where the bathroom air conditioner system 1 is installed. The bathroom remote controller 6 is installed on the wall surface of the bathroom 8. The bathroom remote controller 6 accepts various operation inputs from the user. In addition, the bathroom remote controller 6 notifies the user of various information by display or voice. The bathroom 8 is composed of a washroom area 8a and a bathing area 8b. A bathtub 10 is installed in the bathing area 8b. The heat source machine 2 is installed outdoors in the house where the bathroom air conditioning system 1 is installed. The heat source machine 2 is connected to the bathroom air conditioner 4 by an forward pipe 41 and a return pipe 42.

The heat source machine 2 will be described with reference to FIG. As shown in FIG. 2, the heat source machine 2 includes a heat medium burner 32, a heat medium circulation pump 50, and a systurn 34. The water (heat medium) in the systurn 34 is sent to the heat medium burner 32 through the low temperature heat medium line 36. The heat medium burner 32 burns a flammable gas and heats water by the combustion heat. A heat absorbing fin 32a is provided inside the heat medium burner 32. The endothermic fin 32a is fixed to a pipeline through which water flows, absorbs combustion heat, and transfers it to water. The heat medium circulation pump 50 is provided on the low temperature heat medium line 36, and circulates water along the water circulation path. The position of the heat medium circulation pump 50 is not particularly limited as long as it is on the water circulation path.

The heat source machine 2 includes a low temperature heat medium temperature sensor 38 for measuring the temperature of water and a high temperature heat medium temperature sensor 52. The low-temperature heat medium temperature sensor 38 is arranged in the low-temperature heat medium line 36, and measures the temperature of water before heating by the heat medium burner 32. The high-temperature heat medium temperature sensor 52 is arranged in the high-temperature heat medium pipeline 54, and measures the temperature of water after heating by the heat medium burner 32.

The heat source machine 2 includes a low-temperature heating outbound route 80 and a high-temperature heating outbound route 82. The low temperature heating outbound route 80 is connected to the low temperature heat medium pipe line 36. The high temperature heating outbound route 82 is connected to the high temperature heat medium pipe line 54. The low temperature heating outbound route 80 sends water to the low temperature heating terminal 70. The high temperature heating outbound route 82 sends water to the high temperature heating terminal 72. A low-temperature heat medium valve 84 is provided on the low-temperature heating outbound route 80, and water is selectively supplied to the low-temperature heating terminal 70. A high-temperature heat medium valve 86 is provided on the high-temperature heating outbound route 82, and water is selectively supplied to the high-temperature heating terminal 72. The low-temperature heating terminal 70 and the high-temperature heating terminal 72 heat and dry by dissipating heat from water. The low temperature heating terminal 70 is, for example, a floor heating panel. The high-temperature heating terminal 72 of this embodiment is the bathroom air conditioner 4 described above. The water radiated by the low-temperature heating terminal 70 and the high-temperature heating terminal 72 is sent to the systurn 34 through the heating return path 62.

The high-temperature heating outbound route 82 described above may be referred to as an outbound pipe 41 in the present specification. The outbound pipe 41 (high temperature heating outbound route 82) is a pipe to be connected to the water inlet pipe 44 of the bathroom air conditioner 4 described later. Further, the heating return path 62 described above may be referred to as a return pipe 42 in the present specification. The return pipe 42 (heating return path 62) is a pipe to be connected to the water discharge pipe 45 of the bathroom air conditioner 4 described later. The heat source machine 2 further includes a heat source machine controller 100 that controls the operation of each component of the heat source machine 2.

Next, the bathroom air conditioner 4 will be described. As shown in FIG. 1, the bathroom air conditioner 4 is connected to the heat source machine 2 via the outbound pipe 41 (the high temperature heating outbound route 82 of the heat source machine 2 described above) and the return pipe 42 (the heating return path 62 of the heat source unit 2 described above). It is connected. The going pipe 41 sends the water (heating water) heated by the heat source machine 2 described above to the bathroom air conditioner 4. The return pipe 42 returns the water heat exchanged by the bathroom air conditioner 4 to the heat source unit 2. Although water (heating water) is used as a heat medium in this embodiment, the heat medium is not limited to this, and different heat media may be used depending on the type of the heat source machine 2.

As shown in FIG. 3, the bathroom air conditioner 4 is a device that air-conditions the inside of the bathroom 8. For example, the bathroom air conditioner 4 heats and dries the bathroom 8 and blows air into the bathroom 8. The bathroom air conditioner 4 can operate in the heating operation mode, the drying operation mode, and the ventilation operation mode. The bathroom air conditioner 4 includes a water inlet pipe 44 and a water outlet pipe 45. Further, the bathroom air conditioner 4 includes a gas-liquid heat exchanger 91, a circulation fan 94, a hot water temperature thermistor 92, and a ventilation fan 98. Further, the bathroom air conditioner 4 includes an infrared sensor 96. The infrared sensor 96 is installed toward the bathroom 8. Specifically, the infrared sensor 96 can detect the temperature of the user's head when the user is bathing in the bathtub 10. When the user is not bathing in the bathtub 10, the infrared sensor 96 detects the temperature of the wall surface of the bathtub 10.

The water inlet pipe 44 is a pipe to which the outgoing pipe 41 is connected. The outgoing pipe 41 is connected to one end of the water inlet pipe 44. The water sent to the bathroom air conditioner 4 by the outbound pipe 41 flows into the water inlet pipe 44. The water heated by the heat source machine 2 is sent to the water inlet pipe 44 by the outgoing pipe 41.

The water discharge pipe 45 is a pipe to which the return pipe 42 is connected. The return pipe 42 is connected to one end of the water discharge pipe 45. The water flowing through the discharge pipe 45 flows out to the return pipe 42. The water discharge pipe 45 is provided with a flow rate control valve 93. The flow rate control valve 93 controls the flow rate of water flowing through the water inlet pipe 44 and the water outlet pipe 45. By adjusting the opening degree of the flow rate control valve 93, the flow rate of water flowing through the water inlet pipe 44 and the water outlet pipe 45 can be adjusted.

Further, the other end of the water inlet pipe 44 and the other end of the water outlet pipe 45 are connected to the gas-liquid heat exchanger 91. The water inlet pipe 44 is a pipe that sends the water sent by the outgoing pipe 41 to the gas-liquid heat exchanger 91. Water flows into the gas-liquid heat exchanger 91 from the water inlet pipe 44. The water heated by the heat source machine 2 is sent to the gas-liquid heat exchanger 91 by the water inlet pipe 44. The water discharge pipe 45 is a pipe that returns the water heat-exchanged by the gas-liquid heat exchanger 91 to the return pipe 42. Water flows out from the gas-liquid heat exchanger 91 to the water discharge pipe 45, and water flows out from the water discharge pipe 45 to the return pipe 42.

The gas-liquid heat exchanger 91 is, for example, a hot water coil. The gas-liquid heat exchanger 91 heats air by heat exchange between heated water and air. The gas-liquid heat exchanger 91 heats the air sent into the bathroom 8 by the heat of the water heated by the heat source machine 2 and sent to the gas-liquid heat exchanger 91. Heat exchange is performed in the process of water flowing through the gas-liquid heat exchanger 91.

The circulation fan 94 is arranged adjacent to the gas-liquid heat exchanger 91. The circulation fan 94 is driven by a motor 94a. The circulation fan 94 blows air by rotating. The circulation fan 94 sends the air in the bathroom 8 to the gas-liquid heat exchanger 91, and also sends the air heated by the gas-liquid heat exchanger 91 into the bathroom 8. That is, the circulation fan 94 circulates the air in the bathroom 8 with the gas-liquid heat exchanger 91. The variable louver 97 is arranged at a position facing the circulation fan 94. The variable louver 97 can change the direction of the air blown into the bathroom 8 by the circulation fan 94. The variable louver 97 is driven by a motor 97a.

The hot water temperature thermistor 92 is provided in the water inlet pipe 44. The hot water temperature thermistor 92 detects the temperature of the water flowing through the water inlet pipe 44. The hot water temperature thermistor 92 detects the temperature of the water after being heated by the heat source machine 2 and before the heat is exchanged by the gas-liquid heat exchanger 91.

The ventilation fan 98 is driven by the motor 98a. The ventilation fan 98 ventilates the air in the bathroom 8 by rotating. The ventilation fan 98 exhausts the moist air in the bathroom 8 to the outside of the bathroom 8. In the dry operation mode of the bathroom air conditioner 4, the ventilation fan 98 operates to ventilate the air in the bathroom 8. Further, the ventilation fan 98 does not operate in the heating operation mode and the ventilation operation mode of the bathroom air conditioner 4.

Further, when the bathroom air conditioner 4 is operating in the heating operation mode, the heat source unit 2 is operating. On the other hand, when the bathroom air conditioner 4 is operating in the ventilation operation mode, the operation of the heat source unit 2 is stopped. The bathroom air conditioner 4 further includes an air conditioner controller 110 that controls the operation of various components of the bathroom air conditioner 4.

Next, the main configuration of the control system of the bathroom air conditioning system 1 of this embodiment will be described with reference to FIG. As shown in FIG. 4, the bathroom air conditioner system 1 includes an air conditioner controller 110 that controls the operation of various components of the bathroom air conditioner 4, and a heat source controller 100 that controls the operation of various components of the heat source machine 2. , The bathroom remote controller 6 and the bathroom remote controller 130 are provided. The air conditioning controller 110 includes a non-volatile memory 112, a first timer 114, and a second timer 116. The non-volatile memory 112 stores the first reference time T1 to the fourth reference time T4 and the like used in the abnormality detection process described later. The air conditioning controller 110 and the heat source controller 100 can communicate with each other. Therefore, various operations of the bathroom air-conditioning system 1 can be performed by the cooperative control of the air-conditioning controller 110 and the heat source unit controller 100. Hereinafter, the air conditioning controller 110 and the heat source controller 100 are collectively referred to as a controller.

The air conditioning controller 110 and the heat source controller 100 can communicate with the bathroom remote controller 6 and the outdoor remote controller 130. The out-bathroom remote controller 130 is installed in a room other than the bathroom (for example, a kitchen) of a house in which the bathroom air conditioning system 1 is installed. The out-of-bathroom remote controller 130 accepts various operation inputs from the user, such as the operation of the bathroom air conditioner 4. Further, the remote controller 130 outside the bathroom notifies the user of various information by display or voice.

The bathroom remote controller 6 and the outdoor remote controller 130 are communicably connected to the management device 142 via the wireless LAN router 140. The management device 142 is, for example, a HEMS (Home Energy Management System) controller. The management device 142 is a device installed in the house where the bathroom air conditioning system 1 is installed. The management device 142 manages the supply amount and the consumption amount of electric power and fuel in the house where the bathroom air conditioning system 1 is installed. Further, the management device 142 can be connected to the external network 200. Therefore, the management device 142 can transmit information to the external device of the bathroom air conditioning system 1 via the external network 200. In this embodiment, the management device 142 can transmit information to the terminal device 202 via the external network 200. The terminal device 202 is, for example, a mobile phone, a smartphone, or the like. Further, the terminal device 202 is the property of the resident of the house in which the bathroom air conditioning system 1 is installed. In the management device 142, it is possible to register a destination of abnormality information indicating that an abnormality has been detected by the abnormality detection process described later. The destination of the abnormality information is, for example, the e-mail address of the terminal device 202. The management device 142 can transmit the abnormality information to the designated e-mail address via the external network 200.

(Abnormality detection processing)
Next, the abnormality detection process executed by the controller of the bathroom air conditioning system 1 will be described with reference to FIG. The abnormality detection process is a process executed while the user is bathing in the bathtub 10.

In step S2, the controller monitors whether the user is immersed in the bathtub 10. Specifically, the controller uses the detection result of the infrared sensor 96 to determine whether or not the user is immersed in the bathtub 10. If it is determined that the user is immersed in the bathtub 10 (YES in step S2), the process proceeds to step S4. On the other hand, when it is determined that the user is not immersed in the bathtub 10 (NO in step S2), the controller ends the abnormality detection process. Also, if it is determined that the user has left the bathtub 10 while the abnormality detection process is being executed, the controller also ends the abnormality detection process.

In step S4, the controller starts timing the first timer 114. That is, the controller starts timing the bathing time TB of the user (hereinafter referred to as a bather).

In step S6, the controller monitors that the bathing time TB of the bather elapses from the first reference time T1. When the bathing time TB elapses from the first reference time T1, the controller proceeds to step S8. The case where the bathing time TB elapses from the first reference time T1 is a case where the bather may fall into an abnormal state such as a rash.

In step S8, the controller notifies that the bathroom air conditioner 4 is operated in the ventilation operation mode. Specifically, the controller transmits a first control signal indicating that the bathroom air conditioner 4 is operated in the ventilation operation mode to the bathroom remote controller 6. Upon receiving the signal, the bathroom remote controller 6 notifies that the bathroom air conditioner 4 is operated in the ventilation operation mode. As a result, the bather can know that the blower operation mode is started.

In step S10, the controller determines whether or not the first remote control signal has been received by the time when a predetermined time elapses after the first control signal is transmitted to the bathroom remote control 6. The first remote control signal is a signal transmitted when the bather determines that the operation of the ventilation operation mode of the bathroom air conditioner 4 is unnecessary. After step S8, the bather operates the bathroom remote controller 6, so that the bathroom remote controller 6 transmits the first remote controller signal to the controller. If it is determined that the first remote control signal has been received within the predetermined time (YES in step S10), the process skips step S12 and proceeds to step S14. On the other hand, if it is determined that the first remote control signal has not been received within the predetermined time (NO in step S10), the process proceeds to step S12.

In step S12, the controller starts the blower operation mode. Specifically, the controller drives the variable louver 97 and uses the detection result of the infrared sensor 96 to direct the direction of the air blown by the circulation fan 94 toward the user's head. Further, the controller stops the operation of the heat source machine 2 when the heat source machine 2 is operating. The controller then drives the circulation fan 94. Since the operation of the heat source unit 2 is stopped, the heated water is not supplied from the heat source unit 2 to the bathroom air conditioner 4. Therefore, cool air is blown from the bathroom air conditioner 4 toward the user's head. As a result, it is possible to prevent the user from falling into an abnormal state.

In step S14, the controller monitors that the bathing time TB elapses from the second reference time T2. When the bathing time TB elapses from the second reference time T2, the controller proceeds to step S16. The second reference time T2 is set to be longer than the first reference time T1.

In step S16, the controller notifies that the emergency call of step S22, which will be described later, will be executed. Specifically, the controller transmits a second control signal indicating that an emergency call is to be executed to the bathroom remote controller 6. Upon receiving the signal, the bathroom remote controller 6 notifies that an emergency call is to be executed.

In step S18, the controller determines whether or not the second remote control signal has been received. The second remote control signal is a signal transmitted when the bather determines that an emergency call is unnecessary. After step S16, the bather operates the bathroom remote controller 6, so that the bathroom remote controller 6 transmits a second remote controller signal to the controller. That is, the second remote control signal is transmitted when the bather is not fainted. If it is determined that the second remote control signal has not been received (NO in step S18), the process proceeds to step S20. On the other hand, when it is determined that the second remote control signal has been received (YES in step S18), the abnormality detection process ends. In this case, it is preferable that the bather leaves the bathroom 8 after operating the bathroom remote controller 6.

In step S20, the controller determines whether or not the bathing time TB has passed the third reference time T3. When it is determined that the bathing time TB has passed the third reference time T3 (YES in step S20), the controller proceeds to step S22. The third reference time T3 is set to be longer than the second reference time T2. If the bathing time TB exceeds the third reference time T3, it is highly possible that the bather is in an abnormal state. On the other hand, when it is determined that the bathing time TB has not passed the third reference time T3 (NO in step S20), the process returns to step S18. That is, the controller monitors the reception of the second remote control signal until the bathing time TB elapses from the third reference time T3.

In step S22, the controller executes an emergency call. Specifically, the controller transmits a third control signal indicating that an abnormality of the bather has been detected to the management device 142 via the bathroom remote controller 6 and the wireless LAN router 140. As described above, the management device 142 can be connected to the external network 200. Therefore, when the management device 142 receives the third control signal, the management device 142 transmits the first management signal indicating an abnormality of the bather to the destination registered in the management device 142 via the external network 200. To do. As a result, the first management signal is transmitted to the terminal device 202 of the resident of the house other than the bather (hereinafter referred to as a cohabitant). The cohabitant can know that the bather is in an abnormal state by checking the abnormal information based on the first management signal transmitted to the terminal device 202. Further, in step S22, the controller drives the second timer 116. As a result, the time counting of the elapsed time TP since the transmission of the third control signal is started.

In step S24, the controller determines whether or not the second management signal has been received. The second management signal is transmitted from the management device 142 to the controller. The management device 142 transmits a second management signal to the controller when receiving a terminal signal from the terminal device 202 indicating that the cohabitant has confirmed the abnormality information transmitted to the terminal device 202. That is, after receiving the abnormality information, the cohabitant operates the terminal device 202 to transmit the terminal signal from the terminal device 202 to the management device 142, and then the management device 142 sends the second management signal to the controller. Is sent. When it is determined that the second management signal has been received (YES in step S24), the abnormality detection process ends. This is because it is expected that some kind of treatment will be taken by the cohabitant who confirmed the abnormal information. On the other hand, when it is determined that the second management signal has not been received (NO in step S24), the process proceeds to step S26.

In step S26, the controller determines whether or not the elapsed time TP after transmitting the third control signal has elapsed the fourth reference time T4. When it is determined that the elapsed time TP has not passed the fourth reference time (NO in step S26), the process returns to step S24. That is, the controller monitors the reception of the second management signal until the elapsed time TP elapses from the fourth reference time T4.

On the other hand, when it is determined that the elapsed time TP has passed the fourth reference time T4 (YES in step S26), the process returns to step S22. In this case, the controller has not received the second management signal. Therefore, there is a high possibility that the cohabitant overlooks the abnormal information transmitted to the terminal device 202. Therefore, the controller again transmits the third control signal to the management device 142. As a result, the first management signal is transmitted again from the management device 142 to the terminal device 202 of the cohabitant. As a result, it is possible to increase the possibility that the cohabitant will notice that the bather has fallen into an abnormality. Further, after transmitting the third control signal, the controller resets the second timer 116 and restarts the timing of the second timer 116. As a result, the controller transmits a third control signal to the management device 142 every fourth reference time T4 until it is determined to be YES in step S24.

As described above, when it is determined that the bathing time TB measured by the first timer 114 has passed the third reference time T3, the controller outputs a third control signal indicating an abnormality of the bather. Send to 142. Then, the management device 142 transmits the first management indicating the abnormality of the bather to the destination of the abnormality information registered in the management device 142 via the external network 200. As a result, the abnormality information can be transmitted to the terminal device 202 of the cohabitant. Even when the housemate is out, there is a high possibility that the terminal device 202 is carried with him. Therefore, even when the cohabitant is out, the cohabitant can know the abnormality of the bather by transmitting the first management signal to the terminal device 202. As a result, when the bather falls into an abnormal state, it is possible to increase the possibility that the bather will be appropriately treated.

Further, in the above embodiment, when it is determined that the bathing time TB has passed the second reference time T2, the controller executes the ventilation operation mode and blows air toward the bather. It is effective to blow air toward the bather as a coping method for abnormalities that occur during long-term bathing. Therefore, by blowing air toward the bather, it is possible to prevent the bather from falling into an abnormal state.

Further, in the above embodiment, the controller transmits a second control signal indicating an abnormality of the bather to the bathroom remote controller 6 when it is determined that the bathing time TB has passed the second reference time T2. ing. Upon receiving the second control signal, the bathroom remote controller 6 notifies the bather that there is a risk of falling into an abnormality. As a result, the bather can know that there is a risk of falling into an abnormal state if the bather continues to take a bath.

Further, in the above embodiment, the bathroom air conditioner 4 includes an infrared sensor 96. Therefore, it is possible to simplify the configuration of devices other than the bathroom air conditioner 4 included in the bathroom air conditioner system 1.

Further, in the above embodiment, when the controller does not receive the second management signal by the time when the fourth reference time T4 elapses after transmitting the third control signal to the management device 142, the management device A third control signal is transmitted to 142 again. When the second management signal is not received, it is highly possible that the cohabitant overlooks that the abnormality information based on the first management signal is transmitted to the terminal device 202. Therefore, it is highly possible that appropriate measures have not been taken for bathers who have fallen into an abnormality. When the controller retransmits the third control signal to the management device 142, the management device 142 retransmits the first management signal to the terminal device 202. As a result, it is possible to prompt again to take appropriate measures for the abnormalities of the bather. As a result, it is possible to increase the possibility that appropriate treatment will be given to the bather.

(Correspondence)
A system including a bathroom air conditioning system 1, a wireless LAN router 140, and a management device 142 is an example of a "bathroom abnormality detection system". The infrared sensor 96 is an example of a “human body detection sensor”. The air conditioning controller 110 is an example of a “control device”. The third reference time T3 is an example of the “first predetermined time”. The first reference time T1 is an example of the "second predetermined time". The second reference time T2 is an example of the "third predetermined time". The fourth reference time T4 is an example of the "fourth predetermined time". The third control signal and the first management signal are examples of the "first abnormal signal" and the "second abnormal signal", respectively. The terminal signal and the second management signal are examples of the "first response signal" and the "second response signal", respectively. The second control signal is an example of the "third abnormal signal". The circulation fan 94 and the variable louver 97 are examples of a “blower” and a “wind direction adjusting”, respectively. The bathroom remote controller 6 is an example of a "remote controller".

Although specific examples of the present invention have been described in detail above, these are merely examples and do not limit the scope of claims. The techniques described in the claims include various modifications and modifications of the specific examples illustrated above.

In the above embodiment, different times are set for the first reference time T1 to the third reference time T3. However, the relationship between the first reference time and the third reference time T3 is not limited to the above relationship. For example, the same time may be set in the first reference time T1 to the third reference time T3.

In the above embodiment, in step S22 when YES is determined in step S26 of FIG. 4, the abnormality information is transmitted to the same destination as the previous destination. Instead of this, when a plurality of destinations are registered in the management device 142, the destinations of the abnormality information may be changed.

In the above embodiment, a heat source machine 2 that uses only a gas heat source is used as the heat source machine 2. Instead of this, a heat source machine that uses only a heat pump heat source, or a heat source machine that uses a gas heat source and a heat pump heat source may be used.

In the above embodiment, the controller uses the bathing time TB of the bather to determine whether or not to transmit the first to third control signals. In addition to this, the head temperature of the bather detected by the infrared sensor 96 may be used to determine whether or not to transmit the first to third control signals. For example, when the head temperature of the bather after the lapse of the first reference time has risen by a predetermined temperature or more with respect to the head temperature of the bather immediately after bathing, the first control signal is transmitted. Is. The same applies to the transmission of the second and third control signals. Further, for example, the bathing time TB may be specified based on the temperature rising from the head temperature of the bather immediately after bathing.

In the above embodiment, the infrared sensor 96 is used to determine whether or not the user is bathing in the bathtub 10. Alternatively, an ultrasonic sensor, a microwave sensor, or the like may be used to determine whether or not the user is bathing in the bathtub 10.

The technical elements described herein or in the drawings exhibit their technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques illustrated in the present specification or drawings can achieve a plurality of purposes at the same time, and achieving one of the purposes itself has technical usefulness.

1: Bathroom air conditioner system 2: Heat source unit 4: Bathroom air conditioner 6: Bathroom remote control 8: Bathroom 8a: Washroom area 8b: Bathing area 10: Bathtub 32: Heat medium burner 32a: Heat absorbing fin 34: Systurn 36: Low temperature heat Medium temperature medium temperature sensor 41: Outgoing pipe 42: Return pipe 44: Water inlet pipe 45: Outflow pipe 50: Heat medium circulation pump 52: High temperature heat medium temperature sensor 54: High temperature heat medium temperature sensor 54: High temperature heat medium temperature sensor 54: Heating return route 70: Low-temperature heating terminal 72: High-temperature heating terminal 80: Low-temperature heating outbound route 82: High-temperature heating outbound route 84: Low-temperature heat medium valve 86: High-temperature heat medium valve 91: Gas-liquid heat exchanger 92: Hot water temperature thermista 93: Flow control valve 94 : Circulation fan 94a: Motor 96: Infrared sensor 97: Variable louver 97a: Motor 98: Ventilation fan 98a: Motor 100: Heat source controller 110: Air conditioner controller 112: Non-volatile memory 114: First timer 116: Second timer 130: Air conditioner outside the bathroom 140: Wireless LAN router 142: Management device 200: Network 202: Terminal equipment

Claims (4)

Bathroom air conditioner and
A management device that can be connected to an external network and can communicate with terminal devices via the external network.
A human body detection sensor that detects the presence of a bather when there is a bather in the bathtub,
A control device capable of communicating with the management device,
It is located in the bathroom and is equipped with a remote controller that can communicate with the control device .
The bathroom air conditioner includes a blower unit that blows air into the bathroom and a wind direction adjustment unit that can adjust the wind direction of the blower unit.
The control device is
Based on the information detected by the human body detection sensor, it is determined whether or not there is the bather in the bathtub.
The bathing time, which is the time when the bather is in the bathtub, is measured.
When the bathing time of the bather is equal to or longer than the first predetermined time, a first abnormality signal indicating an abnormality of the bather is transmitted to the management device.
When the management device receives the first abnormality signal, the management device transmits a second abnormality signal indicating the abnormality of the bather to the terminal device via the external network.
The control device is
When it is determined that the bathing time is equal to or longer than the second predetermined time, a first control signal is transmitted to the remote controller.
If the first remote control signal for the first control signal is not received from the remote control by the time when a predetermined time elapses after the first control signal is transmitted to the remote control, the air is blown out from the blower. An abnormality detection system for a bathroom in which the wind direction adjusting unit is operated so that the wind hits the bather, and the air is blown from the air blower toward the bather. Bathroom air conditioner and
A management device that can be connected to an external network and can communicate with terminal devices via the external network.
A human body detection sensor that detects the presence of a bather when there is a bather in the bathtub,
A control device capable of communicating with the management device,
It is located in the bathroom and is equipped with a remote controller that can communicate with the control device .
The bathroom air conditioner includes a blower unit that blows air into the bathroom and a wind direction adjustment unit that can adjust the wind direction of the blower unit.
The control device is
Based on the information detected by the human body detection sensor, it is determined whether or not there is the bather in the bathtub.
The bathing time, which is the time when the bather is in the bathtub, is measured.
When it is determined that the bathing time of the bather is equal to or longer than the third predetermined time, a third abnormal signal is transmitted to the remote controller to the remote controller.
When the bathing time of the bather is equal to or longer than the first predetermined time without receiving the second remote control signal for the third abnormality signal from the remote controller, the first indicating the abnormality of the bather. The abnormal signal of is transmitted to the management device,
When the management device receives the first abnormality signal, the management device transmits a second abnormality signal indicating the abnormality of the bather to the terminal device via the external network.
When it is determined that the bathing time is equal to or longer than the second predetermined time, the control device operates the wind direction adjusting unit so that the wind blown from the blower hits the bather, and the blower unit operates the wind direction adjusting unit. Anomaly detection system in the bathroom that blows air from the bather to the bather. The bathroom abnormality detection system according to claim 1 or 2, wherein the human body detection sensor is provided in the bathroom air conditioner. The management device transmits the second abnormal signal to the terminal device via the external network, and then receives the first response signal from the terminal device to the second abnormal signal via the external network. Is received, a second response signal to the first abnormal signal is transmitted to the control device, and
The control device is
The elapsed time from transmitting the first abnormal signal to the management device is measured, and the elapsed time is measured.
When it is determined that the second response signal has not been received from the management device by the time when the fourth predetermined time elapses, the management device is again provided with the first abnormal signal. The bathroom abnormality detection system according to any one of claims 1 to 3, which is transmitted.

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