JP2020187524A - Health impact measures support system and health impact measures support method - Google Patents

Abstract

To provide a health impact measures support system capable of appropriately reducing effects on the health of users by scattered substances.SOLUTION: The health impact measures support system includes: a storage unit storing a substance allergy calendar where information on the amount of scattering about allergen at each time and test result information concerning the presence or absence of health effects due to the allergen on a predetermined user P; and a server 1 that outputs a piece of information on the affecting period, which is the period during which the user P is affected by allergen based on the allergy calendar, which is information on the timing of allergen scattering in the air, and the test result information.SELECTED DRAWING: Figure 1

Description

The present invention relates to a technology for a health effect countermeasure support system and a health effect countermeasure support method for alleviating health effects such as pollen.

The number of allergic diseases including pollinosis is said to be one in two in Japan, and it is expected to increase further in the future.

In order to alleviate the user's allergic symptoms, for example, the technique described in Patent Document 1 is disclosed. In Patent Document 1, "The user sends the allergen information of the holding member that collects and stably holds the allergen to the center, and the center creates a countermeasure plan based on the allergen information and sends the user. If an agreement is reached to implement the countermeasure plan, the center will implement the countermeasure plan and eliminate allergens. ”The allergy countermeasure system is disclosed (see summary). ..

Further, in Patent Document 2, "The server device 21 has a test result acquisition unit 231 that acquires blood test result data of a subject from a blood test management device of a testing institution, and test result data acquired for predetermined items. The related information acquisition unit 232 that acquires related information related to the health condition of the subject by comparing the data with the reference value data previously recorded in the database, and the related information acquired via the network as a recording medium. A server device, a communication terminal device, an information providing method, a program, and a recording medium including a related information providing unit 234 provided to the above are disclosed (see summary).

Then, Patent Document 3 states, "The air purifier filter system includes an air purifier filter unit and a machine-readable identifier, and the machine-readable identifier depends on the type of the filter unit and the type of the filter unit. Provides information on, among several different pollutants to be filtered, performance information specific to the target pollutant to be filtered by the air purifier filter unit, to provide a life prediction for the filter unit. , Or can be used to advise that the filter should be changed for other reasons, which may give the user a pre-warning and an indication of when to change the filter unit. The instruction to change the filter unit can be more accurate than a simple timer because it can take into account the type and performance information of the filter unit. In some examples, the usage history of the filter unit is used. It is also possible to predict when the filter unit should be changed. ”Air purifiers Filter systems, air purifiers, and methods of controlling air purifiers are disclosed (see summary).

JP-A-2007-26393 Japanese Unexamined Patent Publication No. 2016-10321 Special Table 2018-506319

In the technique described in Patent Document 1, the user must collect the allergen by himself / herself, which is troublesome for the user.
The technique described in Patent Document 2 only guides services and products appropriate for the health management of the subject. Therefore, in the technique described in Patent Document 2, as in the technique described in Patent Document 1, it is necessary for the subject (user) to perform the actions necessary for health management.
The technique described in Patent Document 3 does not describe measures corresponding to allergic symptoms in individual users.

The present invention has been made in view of such a background, and it is an object of the present invention to appropriately reduce the health effects of scattered substances on the user.

In order to solve the above-mentioned problems, the health effect countermeasure support system of the present invention has substance effect information in a storage unit that stores the presence or absence of health effects due to scattered substances in a predetermined person, and the scattering in the air. Having a processing unit that outputs information on an influence period, which is a period during which the person is affected by the scattered substance, based on the scattering amount information, which is information on the timing of the scattering amount of the substance, and the substance influence information. It is a feature.
Other solutions will be described as appropriate in the embodiments.

According to the present invention, it is possible to appropriately reduce the health effect of the scattered substance on the user.

It is a figure which shows the configuration example of the allergy measures support system which concerns on this embodiment. It is a figure which shows the hardware configuration of a server. It is a figure which shows the hardware configuration of Robo Kusei. It is a figure which shows the processing procedure of the allergy measures support system in 1st Embodiment. It is a figure which shows the example of the inspection result information. It is a figure which shows the example of the allergic calendar. It is a flowchart which shows the control procedure of Robo Kusei depending on the presence / absence of a user. It is a figure which shows the procedure of the allergen scattering start / end notification. It is a figure which shows the procedure of the operation capacity control of Robo Kusei. It is a figure which shows the processing procedure of the allergy measures support system in 2nd Embodiment. It is a figure which shows the processing procedure of the allergy measures support system in 3rd Embodiment. It is a figure which shows the procedure of the recommended filter notification processing performed in 4th Embodiment.

Next, an embodiment (referred to as “embodiment”) for carrying out the present invention will be described in detail with reference to the drawings as appropriate.

[First Embodiment]
(system)
FIG. 1 is a diagram showing a configuration example of the allergy countermeasure support system 10 according to the present embodiment.
In FIG. 1, the solid line arrow indicates the transmission and reception of information, and the broken line arrow indicates the exchange other than information.
The allergy countermeasure support system 10 includes a server 1, a robot air purifier (hereinafter referred to as Robo air purifier (air purifier) 2), a mobile terminal 3, and a meteorological server 4 installed in a meteorological company. Here, the mobile terminal 3 is owned by the user P, and the Robo Kusei 2 is leased from the Kusei rental company C2 to the user P. Further, the user P is staying (resident) in the building B, and the Robo Kusei 2 and the like are installed in the building B.

The server 1 and Robo Kusei 2 can communicate with each other via the network NW. Further, the mobile terminal 3 can communicate with the server 1 via wireless communication or the like.
The server 1 calculates and outputs the scattering period of the allergen at which the user P exhibits an allergic reaction. The processing performed by the server 1 will be described later.

Robo Kusei 2 removes pollen, house dust, etc. floating in the indoor air. Further, as will be described later in FIG. 3, the Robo Kusei 2 is provided with a drive device 204, and it is possible to remove pollen, house dust, etc. while moving indoors. As shown in FIG. 3, by equipping the Robo Kusei 2 with the self-positioning device 206, it is possible to grasp in which indoor room and to what extent pollen, house dust, etc. are collected. is there. The Robo Kusei 2 is leased from the Kusei rental company C2 to the user P as described above by receiving an instruction or the like from the server 1.

Further, the server 1 controls the Robo Kusei 2 as needed via the network NW. Then, Robo Kusei 2 transmits operation information including information such as whether it is operating or stopped to the server 1 via the network NW. Further, the server 1 transmits the rental fee information of Robo Kusei 2 to the mobile terminal 3.

The meteorological server 4 is installed in the meteorological company as described above, and notifies the server 1 of the start / end of scattering of the observed pollen, PM2.5, and the like.
The inspection center C1 sends the allergic test kit K to the user P, and inspects which allergic reaction the user P has based on the allergic test kit K sent from the user P. Further, the inspection center C1 transmits the result of the allergy inspection to the server 1.

By the way, each arrow in FIG. 1 indicates a main one, and the exchange of other information and the like will be described as appropriate in FIGS. 3 and later.

(Hardware configuration of server 1)
FIG. 2 is a diagram showing a hardware configuration of the server 1.
The server 1 is a PC (Personal Computer) or the like. A CPU (Central Processing Unit) 101, a RAM (Random Access Memory) 102, a communication device 103, an input device 104, an output device 105, a storage device 106, and the like are connected to the server 1 via a bus. The communication device 103 is a NIC (Network Interface Card) or the like, and is connected to the network NW. The input device 104 is a keyboard or a mouse. The output device 105 is a display device or the like. The storage device 106 is an HD (Hard Disk) or the like.

The program stored in the storage device 106 is loaded into the RAM 102 and executed by the CPU 101. As a result, each process performed by the server 1 can be executed.
The storage device 106 may be provided separately from the server 1 as a database or the like.

(Hardware configuration of Robo Kusei 2)
FIG. 3 is a diagram showing a hardware configuration of Robo Kusei 2.
Robo Kusei 2 has a CPU 201, a ROM (Read Only Memory) 202, a communication device 203, a drive device 204, an output device 205, a self-positioning device 206, and a RAM 207.
When the program stored in the ROM 202 is executed by the CPU 201, each process performed by the Robo Kusei 2 can be executed.
The drive device 204 includes wheels, a motor for rotating the wheels, and the like. As described above, the Robo Kusei 2 can be moved by the drive device 204.
The output device 205 is a liquid crystal display, an LED (Light Emitting Diode), a speaker, or the like, and can notify the user P of the start or end of scattering of the allergen.

The self-positioning device 206 includes a camera, a positioning sensor such as a laser, and the like, and identifies the self-position by a matching process or the like.
The RAM 207 stores control information and the like transmitted from the server 1.

(Processing procedure)
FIG. 4 is a diagram showing a processing procedure of the allergy countermeasure support system 10 in the first embodiment. Refer to FIG. 1 as appropriate.
First, when the user P applies for allergy countermeasures, the inspection center C1 sends the allergy inspection kit K (S101).
The user P collects his / her own blood, attaches his / her own blood to the sent test kit K, and sends it to the test center C1 (S102).

The staff of the test center C1 performs an allergy test with the blood attached to the sent test kit K (S111).
Then, the inspection result information 161 is transmitted from the inspection center C1 to the mobile terminal 3 and the server 1 owned by the user P (S112).

FIG. 5 is a diagram showing an example of inspection result information 161.
The inspection result information 161 is information transmitted from the inspection center C1 and stored in the storage device 106 of the server 1.
As shown in FIG. 5, the inspection result information 161 contains an ID (“ID001”, “ID002”, “ID003”) that identifies the user P, and information regarding the presence or absence of allergies to cedar pollen, ragweed pollen, ... Is stored. In FIG. 5, cedar pollen is referred to as “sugi” and ragweed pollen is referred to as “ragweed”. In the example of FIG. 5, the presence or absence of each allergy is indicated by “◯” and blank. Furthermore, the item of asthma in the example of FIG. 5 is information on whether or not the person has asthma that may be affected by PM2.5.

Further, in the example of FIG. 5, "ID001", "ID002", and "ID003" indicate the user P who lives together.
That is, among the cohabiting "ID001", "ID002", and "ID003", "ID001" has an allergy to cedar pollen, and "ID002" has an allergy to cedar pollen and ragweed pollen. In addition, "ID003" has asthma. Incidentally, whether or not a person has asthma is not an allergic test at the test center C1, but information stored by sending the result of a health diagnosis from a medical institution (not shown) to the server 1.

Returning to the description of FIG.
The server 1 that has received the inspection result information 161 calculates the influence period based on the inspection result information 161 and the allergic calendar 162 (S121).
FIG. 6 is a diagram showing an example of an allergic calendar 162.
The allergic calendar 162 is information stored in the storage device 106 of the server 1.
As shown in FIG. 6, the allergic calendar 162 stores the scattering time of each allergen such as cedar pollen, ragweed pollen, ..., mites, and PM2.5. In the example of FIG. 6, the time when a large amount is scattered is indicated by “⊚”, and the time when a large amount is scattered is indicated by “◯”. The period when it does not scatter is indicated by "x". Although PM2.5 is not exactly an allergen, it is taken up as one of the allergens here because it causes health hazards such as asthma.

The server 1 calculates the influence period based on the inspection result information 161 shown in FIG. 5 and the allergic calendar 162 shown in FIG. Here, the affected period is a period during which the user P is affected by allergies. Here, the period of influence is the period during which a large amount of allergen is scattered (the period indicated by "◎" in FIG. 5), but the period during which the allergen is scattered even if it is not a large amount ("◎" in FIG. "Or" ○ "period).

For example, “ID001” in FIG. 5 has an allergic reaction to Japanese cedar pollen, so the period of influence is from February to April according to FIG.
Further, as described above, since "ID001" to "ID003" in FIG. 5 coexist, the period of influence in this household is the period of influence by cedar pollen, ragweed pollen and PM2.5. Therefore, from FIGS. 5 and 6, the period of influence in the household where "ID001" to "ID003" live together is from February to May and from August to October. In this way, the duration of impact is calculated for each household.
Having such an allergic calendar 162 makes it easy to specify the scattering period of each allergen.

If "ID001" lives alone, the period of influence of "ID001" at home is naturally from February to April, which is the period of influence on Japanese cedar pollen.

Returning to the description of FIG.
The server 1 transmits the influence period calculated in step S121 to the Kusei rental company C2 (S122).
Then, the Kusei rental company C2 sends the Robo Kusei 2 to the user P (home) at the start of the received influence period (S131). That is, Robo Kusei 2 is leased to user P (household).
When the Robo Kusei 2 starts operation, it transmits operation information, which is information on whether or not it is operating, to the server 1 (S132).
Then, when the influence period ends, the user P returns the Robo Kusei 2 to the Kusei rental company C2 (S133). By transmitting the information on the end of the influence period from the server 1 to the mobile terminal 3 owned by the user P, the mobile terminal 3 may display the end of the influence period and the return instruction of Robo Kusei 2.
Next, the server 1 calculates a rental fee (charge) based on the influence period on a monthly basis (S141), and transmits the calculated rental fee (charge) to the mobile terminal 3 of the user P (S142). The rental fee may be separately charged to the user P as an invoice.

By performing the process shown in FIG. 4, the user P operates the Robo Sorasei 2 when the Robo Sorasei 2 is sent, and returns the Robo Sorasei 2 to the Sorasei rental company C2 when the influence period ends. As described above, according to the process shown in FIG. 4, it is possible to appropriately alleviate the allergic symptom of the user P without bothering the user P as much as possible. Further, the user P can hold the Robo Kusei 2 that requires a storage place for a necessary period and return it to the Kusei rental company C2 during the unnecessary period. As a result, the user P can effectively utilize the space in the house (inside the building B) where the Robo Kusei 2 is placed.

(Control of Robo Kusei 2 by presence / absence)
FIG. 7 is a flowchart showing a control procedure of Robo Kusei 2 depending on the presence / absence of user P.
First, it is assumed that Robo Kusei 2 is in operation (S201).
Next, Robo Kusei 2 determines the presence / absence of user P (S202). The presence / absence of the user P is determined based on information sent from a camera installed in the home, a motion sensor, or the like. Alternatively, the presence / absence of the user P may be determined by the sound in the room or the GPS information of the mobile terminal 3 owned by the user P.

If the user P is absent (S202 → absent), Robo Kusei 2 stops the operation (S211), and transmits the operation information to the effect that the operation has stopped (S212). After that, Robo Kusei 2 returns the process to step S202.
If the user P is in the room (S202 → present), Robo Kusei 2 returns the process to step S201. That is, the Robo Kusei 2 continues to operate, or if the Robo Kusei 2 is in the stopped state, the operation is started (S221). Then, Robo Kusei 2 transmits the operation information indicating that it is operating to the server 1 (S222), and returns the process to step S202.

When calculating the rental fee in step S141 of FIG. 4, the server 1 calculates the rental fee by subtracting the fee during the period when Robo Kusei 2 is stopped. Alternatively, the server 1 calculates the charge for the period during which Robo Kusei 2 is stopped as a cashback charge.

According to the process shown in FIG. 7, since the robot air cleaning 2 can be stopped during the period when the user P is absent, efficient operation of the robot air cleaning 2 can be realized.

In addition, Robo Kusei 2 may learn, for example, the return time of the user P on the work day, or the user P may set the return time to Robo Kusei 2. Then, the Robo Kusei 2 may be started to operate 30 minutes before the user P returns home.
The process shown in FIG. 7 may be omitted.

(Notification of start / end of scattering)
FIG. 8 is a diagram showing a procedure for notifying the start / end of scattering of allergens.
When the start of scattering of the allergen is observed, the weather server 4 transmits the scattering start information to the server 1 (S301). The observation of the start of scattering of the allergen may be performed by an employee of a meteorological company in which the meteorological server 4 is installed, or may be performed by an allergen observation device.

The server 1 that has received the scattering start information determines whether or not the allergen that is the target of the scattering start information is an allergen that causes an allergen reaction to the user P (S302). The process of step S302 is performed based on the inspection result information 161 of FIG.
If the allergen that is the target of the scattering start information is an allergen that causes an allergen reaction with the user P, the scattering start information is transmitted (S303). The scattering start information is transmitted to the Robo Kusei 2 leased to the user P and the mobile terminal 3 owned by the user P.
The Robo Kusei 2 and the mobile terminal 3 that have received the scattering start information notify the user P of the start of scattering of the allergen (S304, S305). Robo Kusei 2 notifies the user P of the start of scattering of the allergen via the output device 205.

Then, when the end of allergen scattering is observed, the meteorological server 4 transmits the scattering end information to the server 1 (S311). Observation of the end of allergen scattering may be performed by an employee of a meteorological company in which the meteorological server 4 is installed, or may be performed by an allergen observation device.

The server 1 that has received the scattering end information determines whether or not the allergen that is the target of the scattering end information is an allergen that causes an allergen reaction to the user P (S312). The process of step S312 is performed based on the inspection result information 161 of FIG.
If the allergen that is the target of the scattering end information is an allergen that causes an allergen reaction with the user P, the scattering end information is transmitted (S313). The scattering end information is transmitted to the Robo Kusei 2 leased to the user P and the mobile terminal 3 owned by the user P.
The Robo Kusei 2 and the mobile terminal 3 that have received the scattering end information notify the user P of the end of the allergen scattering (S314, S315). Robo Kusei 2 notifies the user P of the end of allergen scattering via the output device 205.

In FIG. 8, the notification is given on both the mobile terminal 3 and the Robo Kusei 2, but the notification may be given on either side.

By performing the process shown in FIG. 8, the user P can take appropriate allergy countermeasures. In addition, it is possible to confirm whether or not Robo Kusei 2 is operating properly.

(Operating capacity control)
FIG. 9 is a diagram showing a procedure for controlling the operating capacity of Robo Kusei 2.
Up to this point, in the allergen calendar 162 of FIG. 6, Robo Kusei 2 is leased to the user P during the period when the amount of allergen scattered is “⊚”. However, only in FIG. 9, it is assumed that Robo Kusei 2 is leased during the period of "○" in addition to the period of "◎" for the amount of allergen scattered.
First, the server 1 calculates the current operating capacity of Robo Kusei 2 based on the inspection result information 161 of FIG. 5 and the allergic calendar 162 of FIG. 6 (S401). In the allergic calendar 162 of FIG. 6, the server 1 sets the operating capacity of Robo Kusei 2 to "medium" during the period "○" and "large" the operating capacity of Robo Kusei 2 during the period "◎".

For example, in the case of a household in which "ID001" to "ID003" shown in FIG. 5 coexist, the target allergens are cedar pollen, ragweed pollen, and PM2.5. Therefore, if the current period is February-May, August-October, when a large amount of these allergens are scattered, the operating capacity of Robo Kusei 2 will be "large". Further, the server 1 sets the operating capacity of Robo Kusei 2 to "medium" if the current period is other than February to May and August to October.

The server 1 transmits the control information of the Robo Sorasei 2 including the current operating capacity of the Robo Sorasei 2 calculated in step S401 to the Robo Sorasei 2 (S402).
The Robo Kusei 2 that has received the control information controls its own operating capacity so as to be the operating capacity included in the received control information (S403).

By performing the process shown in FIG. 9, the allergic symptom of the user P can be alleviated more appropriately.

[Second Embodiment]
FIG. 10 is a diagram showing a processing procedure of the allergy countermeasure support system 10 in the second embodiment.
In the first embodiment, Robo Kusei 2 is leased according to the allergen scattering situation. In the second embodiment, the Robo Kusei 2 continues to be leased to the user P even during the period when the allergen is not scattered, and the Robo Kusei 2 is operated / stopped according to the allergen scattering status. That is, in the second embodiment, the Robo Kusei 2 is continuously installed in the home of the user P.
Further, in FIG. 10, the same processing as in FIG. 4 is designated by the same reference numerals and the description thereof will be omitted.

When the server 1 calculates the influence period in step S121, the server 1 transmits control information to the Robo Kusei 2 according to the calculated influence period (S501). That is, during the period when the target allergen is "x" or "○", control information is transmitted so as to stop Robo Kusei 2. Here, control information may be transmitted so as to stop Robo Kusei 2 only during the period when the target allergen is "x". Further, if the target allergen is currently in the period of "◎", control information is transmitted so as to operate Robo Kusei 2. As shown in FIG. 9, if the allergen scattering is "◎", the operating capacity of Robo Kusei 2 is set to "Large", and if it is "○", the operating capacity of Robo Kusei 2 is set to "Medium". The control information may be included in the control information transmitted in step S501.

The Robo Kusei 2 that has received the control information performs operation control based on the control information (S511). That is, the Robo Kusei 2 operates / stops itself based on the control information, and controls the operating capacity as needed.
Then, Robo Kusei 2 transmits the operation information to the server 1 (S512). The operation information includes the date and time, information on whether or not the operation is performed, and the like.

The server 1 that has received the operation information calculates the rental fee (charge) based on the operation information (S141a). The process of step S141a may be performed at the timing of charging the rental fee, for example, every month.
The rental fee may be obtained by multiplying the rental fee per hour by the operating period (operating time) of Robo Kusei 2, or may be a cashback of the fee corresponding to the non-operating time from the fixed monthly fee.
Next, the server 1 transmits the calculated rental fee to the mobile terminal 3 of the user P (S142).

In the second embodiment, each process shown in FIGS. 7 to 9 may be performed.
Further, the rental fee may be calculated based on the control information transmitted from the server 1 to the Robo Sorasei 2, or may be calculated based on the operation information transmitted from the Robo Sorasei 2 from the server 1. If the rental fee is calculated based on the operation information, the rental fee is calculated based on the actual operation status of Robo Kusei 2, so that the reliability for the user P is higher.

In the second embodiment, the on / off of the Robo Kusei 2 is controlled according to the allergen scattering state in a state where the Robo Kusei 2 is continuously leased to the user P. In the second embodiment, it is not necessary to send / return Robo Kusei 2 according to the allergen scattering situation, so that the burden on the user P can be reduced. Further, in an environment such as a building where it is preferable that Robo Kusei 2 continues to be leased, the second embodiment is desirable. Further, in a building or the like, it is preferable to cash back the charge corresponding to the non-operating hours from the fixed monthly amount.

[Third Embodiment]
FIG. 11 is a diagram showing a processing procedure of the allergy countermeasure support system 10 in the third embodiment.
In the first embodiment and the second embodiment, the Robo Kusei 2 is leased or the operation is controlled based on the allergic calendar 162 shown in FIG. However, in the third embodiment, the server 1 does not use the allergic calendar 162, and leases Robo Kusei 2 according to the information on the scattering status of allergens transmitted from the meteorological server 4 installed in the meteorological company. An example is shown.

In FIG. 11, the same process as in FIG. 1 is assigned the same step number and the description thereof will be omitted.
Further, FIG. 11 shows an example based on FIG. 1 (first embodiment) (leased by Robo Kusei 2 only for a period). However, the process of FIG. 11 may be based on FIG. 10 (second embodiment) (Robo Kusei 2 continues to be leased).

After the inspection result information 161 is transmitted to the server 1 and the mobile terminal 3 in step S112, the meteorological server 4 transmits the observed allergen scattering start information to the server 1 (S601). The observation of the start of scattering of the allergen may be performed by an employee of a meteorological company in which the meteorological server 4 is installed, or may be performed by an allergen observation device.

The server 1 that has received the scattering start information determines whether or not the allergen that is the target of the scattering start information is an allergen that causes an allergen reaction to the user P (S602). The process of step S602 is performed based on the inspection result information 161 of FIG.
If the allergen is an allergen that causes an allergen reaction to the user P, the server 1 instructs the air-clearing rental company C2 to send the robot air-clearing 2 to the user P (S603).
Upon receiving the instruction to send Robo Kusei 2, the Kusei rental company C2 sends Robo Kusei 2 to user P (home) (S131).

In addition, the meteorological server 4 transmits the observed allergen scattering end information to the server 1 (S611). Observation of the end of allergen scattering may be performed by an employee of a meteorological company in which the meteorological server 4 is installed, or may be performed by an allergen observation device.

The server 1 that has received the scattering end information determines whether or not the allergen that is the target of the scattering end information is an allergen that causes an allergen reaction to the user P (S612). The process of step S612 is performed based on the inspection result information 161 of FIG.
If the allergen is an allergen that causes an allergen reaction with the user P, the server 1 instructs the mobile terminal 3 owned by the user P to return the Robo Kusei 2 (S613).
The user P who receives the return instruction of Robo Kusei 2 returns Robo Kusei 2 to the Kusei rental company C2 (S133).

In the third embodiment, each process shown in FIGS. 7 to 6 may be performed.

According to the process of FIG. 11, it is possible to lease (or control Robo Kusei 2) of Robo Kusei 2 according to the actual allergen scattering situation.

[Fourth Embodiment]
(Recommended filter notification)
FIG. 12 is a diagram showing a procedure of recommended filter notification processing performed in the fourth embodiment.
The process shown in FIG. 12 can be executed in the first to third embodiments.
Since PM2.5 is very small compared to pollen, mites, etc., it is desirable to replace the filter of Robo Kusei 2 with a filter for PM2.5 while PM2.5 is scattered.
First, the server 1 determines whether or not the user P develops a health hazard due to PM2.5 (S701). In the example of the test result information 161 of FIG. 5, since "ID003" has asthma and causes health damage due to PM2.5, the user P (home) of "ID003" is the target of filter replacement.

If the user P develops a health hazard due to PM2.5, the server 1 determines the filter replacement time (S702). As shown in FIG. 6, the time to replace the filter for allergens other than PM2.5 with the filter for PM2.5 is March. In addition, the replacement period from the filter for PM2.5 to the filter for allergens other than PM2.5 is June.
If the current time corresponds to the filter replacement time, the server 1 transmits the filter information to the mobile terminal 3 of the user P (S703). The filter information includes information on filter replacement, such as replacement of a filter for an allergen other than PM2.5 with a filter for PM2.5.
The mobile terminal 3 that has received the filter information displays the recommended filter at the current time (S711), and prompts the user P to replace the filter.

The mobile terminal 3 to which the filter replacement time is transmitted may be the mobile terminal 3 of the person (“ID003” in the example of FIG. 3) who causes health damage due to PM2.5, or the representative mobile terminal 3. For example, in a household where "ID001" to "ID003" in FIG. 3 live together, if the user P of "ID001" is registered as a representative, a filter exchange instruction is given to the mobile terminal 3 of "ID001" as the representative. May be sent.

Although the filter information is transmitted to the mobile terminal 3 here, it may be transmitted to the Robo Kusei 2 or may be transmitted to both the mobile terminal 3 and the Robo Kusei 2. When the filter information is transmitted to Robo Kusei 2, the recommended filter is displayed on the output device 205 of Robo Kusei 2.

According to the treatment shown in FIG. 12, the filter of Robo Kusei 2 can be reliably replaced according to the type of scattered allergen (scattering substance having a health effect). As a result, the allergic symptom (health effect) of the user P can be reduced.

The present invention is not limited to the above-described embodiment, and includes various modifications. For example, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to those having all the described configurations. Further, it is possible to replace a part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Further, it is possible to add / delete / replace a part of the configuration of each embodiment with another configuration.

Robo Kusei 2 is leased from Kusei rental company C2 to user P, but it may be purchased by user P. In this case, the second embodiment or the third embodiment based on the second embodiment is performed.

Further, in an environment such as a school or a university where there is a long vacation, Robo Kusei 2 may be stopped during the long vacation. The stop of Robo Kusei 2 may be performed based on the control information from the server 1.
Further, the Robo Kusei 2 may transmit the amount of allergen dust collected per day to the server 1 via the network NW. The server 1 may calculate the actual amount of allergens scattered in the relevant area based on the amount of dust collected per day transmitted, and reflect it in the allergen calendar 162 of the next year. Alternatively, the Robo Kusei 2 may transmit the amount of allergen dust collected per day in each room to the server 1.

Further, in the present embodiment, the test result information 161 of the user P is obtained by analyzing the blood of the user P attached to the test kit K for allergies. However, the present invention is not limited to this, and test result information 161 may be obtained by a skin test, a food load test, or the like.

Further, although an air purifier (Robo Air Purifier 2) is used in this embodiment, a stationary air purifier may be used. Alternatively, an air conditioner with an air purifying function, a robot vacuum cleaner, or the like may be used.
In the allergic calendar 162, the amount of scattered allergens is stored on a monthly basis, but it may be stored on a monthly basis at the beginning, middle, or end of the month, or on a daily basis. Alternatively, the amount of allergic scattering per hour or minute may be stored in the allergic calendar 162 in the form of a graph or the like.

Further, each of the above-mentioned configurations, functions, storage devices 106 and the like may be realized by hardware, for example, by designing a part or all of them by an integrated circuit or the like. Further, as shown in FIGS. 2 and 3, each of the above-described configurations, functions, and the like may be realized by software by interpreting and executing a program in which a processor such as a CPU 101 or 201 realizes each function. .. In addition to storing information such as programs, tables, and files that realize each function in HD, memory, recording devices such as SSD (Solid State Drive), IC (Integrated Circuit) cards, and SD (Secure) It can be stored in a recording medium such as a Digital) card or a DVD (Digital Versatile Disc).
Further, in each embodiment, the control lines and information lines are shown as necessary for explanation, and not all the control lines and information lines are necessarily shown in the product. In practice, almost all configurations can be considered interconnected.

1 server (processing unit)
2 Robo Air Purifier (Air Purifier, Robot Air Purifier, Notification)
3 Mobile terminal (notification section)
4 Meteorological server (Meteorological observation department)
10 Allergy countermeasure support system (health impact countermeasure support system)
161 Test result information (substance effect information)
162 Allergic calendar (scattering amount information, substance scattering amount information)
B Building S121 Impact period calculation (impact period generation step)
S122 Impact period transmission (impact period output step)

Claims (13)

The storage unit has substance effect information that stores the presence or absence of health effects of scattered substances in a predetermined person.
A process of outputting information on an influence period, which is a period during which the person is affected by the scattered substance, based on the scattering amount information, which is information on the timing of the scattering amount of the scattered substance in the air, and the substance influence information. A health effect countermeasure support system characterized by having a department. The health according to claim 1, wherein the storage unit stores substance scattering amount information in which information on the scattering amount of the scattered substance at each time is stored as the scattering amount information. Impact countermeasure support system. The health effect countermeasure support system according to claim 1, wherein the air purifying unit installed in the building where the person stays operates during the effect period. The health effect countermeasure support system according to claim 1, wherein an air purifying unit installed in a building in which the person stays receives information on the impact period and operates during the impact period. The scattering amount information stores information on the amount of the scattered substance at each of the times.
Information on the amount of the scattered substance is stored in the information on the period of influence.
The health effect countermeasure support system according to claim 1, wherein the air purifying unit installed in the building in which the person stays adjusts the operating capacity according to the amount of the scattered substance. The processing unit
Received information on the start time of scattering of the scattered material and information on the end time of scattering from the meteorological observation department.
The received information on the scattering start time and the information on the scattering end time are transmitted to the notification unit.
The notification unit
The health effect countermeasure support system according to claim 1, wherein the person is notified of information on the scattering start time and information on the scattering end time. An air purifier is installed in the building where the person stays.
It has an presence / absence information notification unit that transmits information for determining the presence / absence of a person in the building in which the air purification unit is installed to the air purification unit.
The air purifier
The health effect countermeasure support system according to claim 1, wherein the operation is stopped when a person is absent in the building in which the air purifying unit is installed. The health effect countermeasure support system according to claim 1, wherein the scattering amount information is based on the scattering amount of the scattered substance transmitted from the meteorological observation unit. An air purifier is installed in the building where the person stays.
The processing unit
The health effect countermeasure support system according to claim 1, wherein the person is notified of the type of the filter of the air purifying unit suitable for the currently scattered scattered substance. The health effect countermeasure support system according to claim 1, wherein the scattered substance is a substance that causes a health effect on the person. The health effect countermeasure support system according to claim 10, wherein the substance that causes a health effect on the person is a specific pollen. In the building where the person stays, an air purifier that removes the scattered substances in the air is installed.
The health effect countermeasure support system according to claim 1, wherein the air purifier is a robot air purifier that can move autonomously while specifying its own current value. It is a health effect countermeasure support method of a health effect countermeasure support system that has substance effect information in the storage unit that stores the presence or absence of health effects due to scattered substances in a predetermined person.
The effect of generating information on the influence period, which is the period during which the person is affected by the scattered substance, based on the scattering amount information, which is information on the timing of the scattering amount of the scattered substance in the air, and the substance influence information. Period generation step and
The impact period output step that outputs the impact period, and
A method of supporting measures against health effects, which is characterized by implementing.

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