Isolated person monitoring method, storage medium, portable electronic equipment, mask, monitoring device and isolated person monitoring system
Technical Field
The invention relates to the technical field of monitoring, in particular to an isolated person monitoring method, a storage medium, a portable electronic device, a mask, a monitoring device and an isolated person monitoring system.
Background
Pneumonia, such as novel coronavirus pneumonia, is an acute respiratory infectious disease caused by viral infection, and the viral transmission routes mainly include respiratory droplet transmission and contact transmission, and the infectivity is extremely high. Therefore, persons suspected of having diseases need to be isolated in an isolation area, which is usually not allowed to leave the isolation area, and if the isolation person needs to leave the isolation area in a special case, the isolation person needs to wear a mask when leaving the isolation area.
Disclosure of Invention
The invention aims to solve the technical problem of how to monitor the behavior of an isolated person so as to reduce the risk of disease transmission.
In order to solve the technical problem, the invention provides an isolated person monitoring method which is characterized by being carried out by utilizing an isolated person monitoring device, wherein the isolated person monitoring device comprises a mask and a positioning module, identity correspondence is carried out on the mask, and the mask is provided with a wearing detection device, and the monitoring method comprises the following steps:
A. the positioning module is used for acquiring whether the isolated personnel is located in the isolated area in real time,
B. whether the mask of the isolation person is worn or not is known in real time by using the wearing detection device,
C. an alarm is given;
wherein, the triggering conditions of the step C comprise: C1. it is known that the person to be isolated is not located in the isolation area and that the mask of the person to be isolated is not worn.
Preferably, the triggering condition of step B includes: knowing that its isolated personnel are not located within the isolated area.
Preferably, a camera is arranged outside the isolation area; the monitoring method comprises the following steps of F, calling a camera to obtain a real-time face state image of an involved person after the condition C1 is met, and acquiring whether the mask of the person is actually worn or not in real time according to the face state image; the triggering conditions of step C include: C2. it was learned that the mask of the isolated person was not actually worn.
Preferably, the cameras are distributed in different areas; the monitoring method comprises the following steps of A1, acquiring the position information of an isolated person in real time by using a positioning module; and calling the cameras, specifically, calling the cameras around the position according to the acquired position information of the isolated personnel.
Preferably, step a1 belongs to step a, and step a determines whether the isolated person is located in the isolated area according to the acquired location information.
Preferably, the monitoring method is suitable for a portable electronic device which is in a distant communication connection with a mask, and the positioning module belongs to a part of the portable electronic device.
The invention also provides a computer-readable storage medium, on which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of the monitoring method as described above.
The invention also provides a control center, which comprises a controller and a wireless communication module which are connected with each other, wherein the controller comprises a processor and a computer readable storage medium which are connected with each other, and the control center is characterized in that: the controller is connected with the positioning module and the wearing detection device through wireless communication of the wireless communication module, the mask to which the wearing detection device belongs and the positioning module correspond in identity to form the isolated person monitoring device, and the computer readable storage medium is as described above.
The invention also provides a portable electronic device, which comprises a controller, a wireless communication module and a positioning module, wherein the controller is respectively connected with the wireless communication module and the positioning module, the controller comprises a processor and a computer readable storage medium which are mutually connected, the positioning module is used as a part of the isolated personnel monitoring device, the isolated personnel monitoring device comprises a mask corresponding to the identity of the positioning module, and the mask is provided with a wearing detection device; the controller is connected to the wear detection device through the wireless communication module in a wireless communication manner, and the computer readable storage medium of the controller sends out an alarm through the wireless communication module in step C.
The invention also provides a mask, which comprises a controller, a wireless communication module and a wearing detection device, wherein the controller is respectively connected with the wireless communication module and the wearing detection device, the controller comprises a processor and a computer readable storage medium which are mutually connected, the mask is used as a part of an isolated person monitoring device, and the isolated person monitoring device comprises a positioning module which is corresponding to the identity of the mask; the controller is communicatively coupled to the location module, the computer readable storage medium of the controller is as described above, and in step C, an alarm is issued via the wireless communication module.
Preferably, the controller is in wireless communication connection with the positioning module through a wireless communication module.
Preferably, the wear detection device is a respiratory airflow sensor or a temperature sensor; in the step B, whether the mask is worn or not is known in real time according to the respiratory airflow related signals detected by the respiratory airflow sensor in real time, or whether the mask is worn or not is known in real time according to the gas temperature or the skin temperature detected by the temperature sensor in real time.
The invention also provides an isolated personnel monitoring device which comprises the mask and the positioning module, wherein the positioning module is arranged on the mask, and a controller of the mask is in communication connection with the positioning module.
The invention also provides an isolated personnel monitoring system, which comprises a controller, wherein the controller comprises a processor and a computer readable storage medium which are connected with each other, and comprises at least one pair of isolated personnel monitoring devices, each pair of isolated personnel monitoring devices comprises a mask and a positioning module, the masks are subjected to identity correspondence, the masks are provided with wearing detection devices, the positioning modules and the wearing detection devices are in communication connection with the controller, and the computer readable storage medium of the controller is as described above.
Preferably, a control center is included, and the controller of the monitoring system is a controller of the control center.
Preferably, the monitoring system comprises a portable electronic device, and the controller of the monitoring system is a controller of the portable electronic device.
Preferably, the on-body electronic device is as described above.
Preferably, the on-body electronic device comprises said positioning module.
Preferably, the controller of the monitoring system is used as the controller of the mask.
Preferably, a control center is included, and in step C, an alarm is issued to the control center.
Preferably, the wear detection device is a respiratory airflow sensor or a temperature sensor; in the step B, whether the mask is worn or not is known in real time according to the respiratory airflow related signals detected by the respiratory airflow sensor in real time, or whether the mask is worn or not is known in real time according to the gas temperature or the skin temperature detected by the temperature sensor in real time.
Preferably, the positioning module is provided on the mask.
Preferably, the monitoring method comprises a camera arranged outside the isolation area, the controller is in communication connection with the camera, and the computer program realizes the steps of the monitoring method when being executed by the processor.
Preferably, the cameras are distributed in different areas, and the computer program is executed by the processor to implement the steps of the monitoring method.
The invention has the following beneficial effects: knowing that the isolation personnel is not located in the isolation area and knowing that the mask is not worn means that the isolation personnel leaves the isolation area to go outside without wearing the mask, which causes a greater risk of disease transmission, thus giving an alarm so that the staff can take measures in time to reduce the risk of disease transmission.
Drawings
FIG. 1 is a connection block diagram of an isolated personnel monitoring system.
Description of reference numerals: 1-a control center; 2-isolating personnel monitoring devices; 3-a monitoring camera; 4-mask; 5-a positioning module; 6-portable electronic equipment; 7-a controller on the portable electronic device; 8-wireless communication module on the portable electronic device; 9-a controller on the mask; 10-a respiratory airflow sensor; 11-wireless communication module on the mask; 12-a controller of a control center; 13-wireless communication module of control center; 14-display.
Detailed Description
Exemplary embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present application are shown in the drawings, it should be understood that the present application can be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.
The controller mentioned below includes a processor and a computer-readable storage medium connected to each other, and a computer program is stored in the computer-readable storage medium, and the computer program implements the functions of the controller when executed by the processor, respectively.
The isolated personnel monitoring system comprises a control center 1, isolated personnel monitoring devices 2 and a plurality of monitoring cameras 3, wherein the isolated personnel monitoring devices 2 are multiple in pairs, each pair corresponds to one isolated personnel, and a connection block diagram of the isolated personnel monitoring system is shown in fig. 1 by taking one isolated personnel monitoring device 2 as an example.
The isolated person monitoring device 2 comprises a mask 4 and a positioning module 5 which are subjected to identity correspondence, the positioning module 5 is arranged in a portable electronic device 6, for example, a mobile phone and a positioning bracelet are provided with the positioning module 5, the portable electronic device 6 is further provided with a controller 7 and a wireless communication module 8, and the controller 7 is respectively connected with the positioning module 5 and the wireless communication module 8. Gauze mask 4 includes controller 9, respiratory airflow sensor 10 and wireless communication module 11, and wherein controller 9 connects respiratory airflow sensor 10 and wireless communication module 11 respectively, and respiratory airflow sensor 10 establishes in the inboard of gauze mask 4, establishes the one side towards the people's face after gauze mask 4 is worn promptly.
The mask 4 and the portable electronic device 6 are specifically subjected to identity correspondence in one of the following two ways: (1) numbering each mask 4, and burning and recording the number information in the controller 9 of the mask 4 in advance, because the portable electronic equipment 6 usually has a recording function, when a worker distributes the masks 4, the worker can download recording software by using the portable electronic equipment 6 of an isolator, and then record the number of the mask 4 of the isolator on the recording software, so that the portable electronic equipment 6 of the isolator is bound with the mask 4, and the mask 4 corresponds to the portable electronic equipment 6 in identity; (2) a biological authentication module (not shown in the figure) is arranged on the mask 4, such as a fingerprint authentication module or a living body detection module, and an isolated person can bind the mask 4 by recording a fingerprint or a living body face; the portable electronic device 6, such as a mobile phone, a positioning bracelet, etc., has a real-name authentication function, and the isolating person bound with the mask 4 can bind the portable electronic device 6 in a real-name authentication manner, so that the mask 4 and the portable electronic device 6 are respectively bound with the same isolating person, and the mask 4 and the portable electronic device 6 are in identity correspondence.
The control center 1 comprises a controller 12, a wireless communication module 13 and a display 14, wherein the controller 12 is respectively connected with the wireless communication module 13 and the display 14, and the wireless communication module 13 of the control center 1 is respectively and wirelessly connected with the wireless communication module 8 of the portable electronic device 6, the wireless communication module 11 of the mask 4 and each monitoring camera 3 through a network.
Example 1
In this embodiment, the controller 12 of the control center 1 monitors the isolated personnel.
The respiratory airflow sensor 10 is a respiratory airflow sensor disclosed in patent document CN 205493782U, and the controller 9 of the mask 4 can know whether the mask 4 is worn or not in real time by using the respiratory airflow sensor 10 and wirelessly transmit related wearing information to the controller 12 of the control center 1 through a network, specifically: after an isolated person wears the mask 4, the breathing airflow sensor 10 is arranged on one side, facing the face, of the mask 4, so that the breathing airflow sensor 10 can acquire relevant signals of breathing airflow of the isolated person in real time and send the relevant signals of the breathing airflow to the controller 9, the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the relevant signals of the breathing airflow, and information that the mask 4 is worn by the isolated person is wirelessly sent to the controller 12 of the control center 1 through a network; after the mask 4 is taken off by the isolater, the breathing gas flow sensor 10 cannot acquire the relevant signals of the breathing gas flow of the isolater, and the controller 9 accordingly learns that the mask 4 is not worn by the isolater in real time and wirelessly transmits the information that the mask 4 is not worn by the isolater to the controller 12 of the control center 1 through the network.
Respiratory airflow sensor 10 can be replaced by a temperature sensor, and controller 9 can know whether mask 4 is worn by an isolated person in real time by using the temperature sensor, and wirelessly send related wearing information to controller 12 of control center 1 through a network, specifically: after the mask 4 is worn by the isolation person, the temperature sensor can detect the temperature of the exhaled air of the isolation person in real time or the skin temperature of the isolation person in real time and send corresponding temperature data to the controller 9, the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the corresponding temperature data, and information that the mask 4 is worn by the isolated person is wirelessly sent to the controller 12 of the control center 1 through the network; after the mask 4 is taken off by the isolating person, the temperature sensor cannot detect the temperature of the gas exhaled by the isolating person and cannot detect the skin temperature of the isolating person, so that the temperature data sent to the controller 9 by the temperature sensor becomes lower obviously, the controller 9 accordingly learns that the mask 4 is not worn by the isolating person in real time, and information that the mask 4 is not worn by the isolating person is sent to the controller 12 of the control center 1 in a wireless mode through the network.
People usually carry the portable electronic device 6 with them, so the position information of the portable electronic device 6 can be used as the position information of the isolated person bound with the portable electronic device 6.
When the monitoring system of the isolation personnel operates, the controller 7 of the portable electronic device 6 utilizes the positioning module 5 to position the position information of the portable electronic device 6 in real time, the controller 12 of the control center 1 acquires the position information of the portable electronic device 6 in real time through the network, namely, the position information of the isolation personnel is acquired in real time, and whether the isolation personnel is located in an isolation area or not is known in real time according to the position information, specifically: if the person in the isolation area is known to be located in the isolation area, the person in the isolation area does not leave the isolation area, and therefore the person in the isolation area does not need to wear the mask 4; if the isolation personnel is not located in the isolation area, the isolation personnel is away from the isolation area, so the isolation personnel needs to wear the mask 4 to reduce the risk of disease transmission. Therefore, after knowing that the isolated person leaves the isolated area, the controller 12 of the control center 1 also knows in real time whether the mask 4 is worn by using the respiratory airflow sensor 10 of the mask 4 bound to the isolated person through the network, specifically: if the mask 4 is not worn, it means that the isolated person leaves the isolated area and does not wear the mask 4, which poses a greater risk of disease transmission; if it is known that the mask 4 is worn, it means that the isolated person leaves the isolated area but wears the mask 4, which does not pose a great risk of disease transmission.
In this embodiment, each monitoring camera 3 is respectively arranged in a main street and a small street outside the isolation area, thereby forming an skynet monitoring system. The controller 12 of the control center 1 learns that the isolation personnel is not located in the isolation area according to the position information of the isolation personnel, and learns that the mask 4 bound with the isolation personnel is not worn, and can call the monitoring camera 3 around the position according to the position information of the isolation personnel, and the monitoring camera 3 is utilized to acquire the face state image of the isolation personnel, and then the mask 4 is learned whether actually worn according to the face state image in real time: if it is known that the mask 4 is not actually worn, it means that the mask 4 may be picked up by an isolated person, which causes a large risk of disease transmission, so the controller 12 of the control center 1 uses the display 11 to issue an alarm so that a worker can take measures in time, thereby reducing the risk of disease transmission; knowing that the mask 4 is actually worn means that there may be an accident that may result in the respiratory airflow sensor 10 not accurately detecting whether the mask 4 is worn, for example, the respiratory airflow sensor 10 is damaged or an isolated person wears another mask, which does not pose a significant risk of disease transmission, so the controller 12 of the control center 1 does not issue an alarm.
In the above-mentioned situation that the mask 4 is actually worn, there are other unexpected situations that may cause the respiratory airflow sensor 10 to be unable to accurately detect whether the mask 4 is worn, for example, the isolated person stops breathing, in such an unexpected situation, the controller 12 of the control center 1 should send an alarm to enable the staff to take rescue measures for the isolated person in time, therefore, after knowing that the mask 4 is actually worn, the controller 12 of the control center 1 identifies the behavior posture of the isolated person by using the monitoring camera 3 through the network, and the controller 12 of the control center 1 can know whether the isolated person falls down according to the behavior posture of the isolated person: if it is known that the isolated person has not fallen, this means that the respiratory airflow sensor 10 is damaged, so the controller 12 of the control center 1 does not issue an alarm; if the isolated person is known to fall, this means that the isolated person may stop breathing, so the controller 12 of the control center 1 uses the display 11 to give an alarm to enable the operator to take rescue measures for the isolated person in time. It is conventional technology to identify the behavior posture of a person by using the monitoring camera 3 and judge whether the person falls down according to the behavior posture of the person, and the details are not repeated herein.
Non-preferably, be equipped with orientation module on gauze mask 4, this orientation module connects controller 9 of gauze mask 4, then controller 9 of gauze mask 4 can utilize this orientation module to fix a position out the positional information of gauze mask 4 as isolation personnel's positional information in real time, and isolation personnel monitored control system need not to set up portable electronic equipment 6 like this and also can acquire isolation personnel's positional information to learn whether isolation personnel are located the isolation region according to isolation personnel's positional information. If the isolation personnel do not carry the mask 4 when leaving the isolation area, the controller 12 of the control center 1 may misjudge that the isolation personnel are still located in the isolation area, so that it is not known that the mask 4 is not worn, and the worker may not take measures for the isolation personnel, thereby causing the risk of disease transmission. Considering that people usually carry the mobile phone or the portable electronic equipment 6 such as the positioning bracelet and the like when going out, the user can preferably acquire the position information of the isolation personnel in real time by utilizing the portable electronic equipment 6 such as the mobile phone or the positioning bracelet and the like to more accurately judge whether the isolation personnel is located in the isolation area, so that the user can timely know whether the mask 4 is worn or not to reduce the risk of disease propagation.
In this embodiment, the mask 4 and the portable electronic device 6 can be connected via bluetooth, so that if the controller 12 of the control center 1 knows that the isolated person is not located in the isolated area and the controller 7 of the portable electronic device 6 cannot realize bluetooth connection with the wearing detection device 10 of the mask 4 of the isolated person, it means that the isolated person leaves the isolated area with the portable electronic device 6 without carrying the mask 4, and therefore the controller 12 of the control center 1 considers that the mask 4 of the isolated person is not worn, and the display 14 is used to give an alarm, so that the worker can take measures to the isolated person in time, thereby reducing the risk of disease transmission.
Example 2
In this embodiment, the controller 7 of the portable electronic device 6 monitors the isolated person.
The respiratory airflow sensor 10 is a respiratory airflow sensor disclosed in patent document CN 205493782U, and the controller 9 of the mask 4 can know whether the mask 4 is worn or not in real time by using the respiratory airflow sensor 10 and wirelessly transmit related wearing information to the controller 7 of the portable electronic device 6 through the network, specifically: after an isolated person wears the mask 4, the breathing airflow sensor 10 is arranged on one side, facing the face, of the mask 4, so that the breathing airflow sensor 10 can acquire relevant signals of breathing airflow of the isolated person in real time and send the relevant signals of the breathing airflow to the controller 9, the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the relevant signals of the breathing airflow, and information that the mask 4 is worn by the isolated person is wirelessly sent to the controller 7 of the portable electronic device 6 through a network; after the mask 4 is taken off by the isolation person, the breathing airflow sensor 10 cannot acquire the relevant signals of the breathing airflow of the isolation person, the controller 9 accordingly learns that the mask 4 is not worn by the isolation person in real time, and wirelessly transmits the information that the mask 4 is not worn by the isolation person to the controller 7 of the portable electronic device 6 through the network.
Respiratory airflow sensor 10 can be replaced by a temperature sensor, and controller 9 can use the temperature sensor to know whether mask 4 is worn by the isolated person in real time, and wirelessly send the relevant wearing information to controller 7 of portable electronic device 6 through the network, specifically: after the mask 4 is worn by the isolation person, the temperature sensor can detect the temperature of the exhaled air of the isolation person in real time or the skin temperature of the isolation person in real time, corresponding temperature data are sent to the controller 9, the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the corresponding temperature data, and information that the mask 4 is worn by the isolated person is sent to the controller 7 of the portable electronic device 6 in a wireless mode through a network; after the mask 4 is taken off by the isolating person, the temperature sensor cannot detect the temperature of the gas exhaled by the isolating person and cannot detect the skin temperature of the isolating person, so that the temperature data sent to the controller 9 by the temperature sensor becomes lower obviously, the controller 9 learns that the mask 4 is not worn by the isolating person in real time, and information that the mask 4 is not worn by the isolating person is sent to the controller 7 of the portable electronic device 6 in a wireless mode through a network.
People usually carry the portable electronic device 6 with them, so the position information of the portable electronic device 6 can be used as the position information of the isolated person bound with the portable electronic device 6.
When the isolated person monitoring system operates, the controller 7 of the portable electronic device 6 utilizes the positioning module 5 to position the position information of the portable electronic device 6 in real time, namely position the position information of the isolated person in real time, and learns whether the isolated person is located in the isolated area or not in real time according to the position information, specifically: if the person in the isolation area is known to be located in the isolation area, the person in the isolation area does not leave the isolation area, and therefore the person in the isolation area does not need to wear the mask 4; if the isolation personnel is not located in the isolation area, the isolation personnel is away from the isolation area, so the isolation personnel needs to wear the mask 4 to reduce the risk of disease transmission. Therefore, after knowing that the isolated person leaves the isolated area, the controller 7 of the personal electronic device 6 also knows in real time whether the mask 4 bound to the isolated person is worn or not by using the respiratory airflow sensor 10 through the network, specifically: if the mask 4 is not worn, it means that the isolated person leaves the isolated area and does not wear the mask 4, which poses a greater risk of disease transmission; if it is known that the mask 4 is worn, it means that the isolated person leaves the isolated area but wears the mask 4, which does not pose a great risk of disease transmission.
In this embodiment, each monitoring camera 3 is respectively arranged in a main street and a small street outside the isolation area, thereby forming an skynet monitoring system. Controller 7 of personal electronic equipment 6 learns that this isolation personnel is not located the isolation region according to isolation personnel's positional information, and learns to bind this isolation personnel's gauze mask 4 and not worn the back, can call the peripheral surveillance camera 3 in this position according to this isolation personnel's positional information, utilizes this surveillance camera 3 to acquire this isolation personnel's face state image in real time, and whether this gauze mask 4 is actually worn according to this face state image real-time acquisition again: if the mask 4 is not worn actually, it means that the mask 4 may be picked up by an isolated person, which causes a large risk of disease transmission, so the controller 7 of the portable electronic device 6 sends an alarm to the controller 12 of the control center 1 through the network, and the controller 12 of the control center 1 displays the alarm to a worker through the display 14 after receiving the alarm, so that the worker can take measures in time, thereby reducing the risk of disease transmission; knowing that the mask 4 is actually worn means that there may be an accident that may result in the respiratory airflow sensor 10 not accurately detecting whether the mask 4 is worn, e.g. the respiratory airflow sensor 10 is damaged or an isolated person wears another mask, which does not pose a significant risk of disease transmission, so the controller 7 of the wearable electronic device 6 does not issue an alarm.
Under the above-mentioned circumstance that the mask 4 is actually worn, there are other unexpected circumstances that may cause the respiratory airflow sensor 10 to be unable to accurately detect whether the mask 4 is worn, for example, the isolated person stops breathing, under such an unexpected circumstance, the controller 7 of the portable electronic device 6 should send an alarm to enable the staff to take rescue measures for the isolated person in time, therefore, after knowing that the mask 4 is actually worn, the controller 7 of the portable electronic device 6 identifies the behavior posture of the isolated person through the monitoring camera 3 via the network, and the controller 7 of the portable electronic device 6 can know whether the isolated person falls down according to the behavior posture of the isolated person: if it is known that the isolated person has not fallen, this means that the respiratory airflow sensor 10 is damaged, so the controller 7 of the on-board electronic device 6 does not issue an alarm; if the isolated person falls down, the isolated person may stop breathing, so the controller 7 of the portable electronic device 6 sends an alarm to the controller 12 of the control center 1 through the network, and the controller 12 of the control center 1 displays the alarm to the worker through the display 14 after receiving the alarm, so that the worker can timely take rescue measures for the isolated person. It is conventional technology to identify the behavior posture of a person by using the monitoring camera 3 and judge whether the person falls down according to the behavior posture of the person, and the details are not repeated herein.
In this embodiment, the mask 4 and the portable electronic device 6 can be connected via bluetooth, so the controller 7 of the portable electronic device 6 knows that the isolated person is not located in the isolated area, and the controller 7 of the portable electronic device 6 cannot realize bluetooth connection with the wearing detection device 10 of the mask 4 of the isolated person, which means that the isolated person leaves the isolated area with the portable electronic device 6 without carrying the mask 4, so the controller 7 of the portable electronic device 6 considers that the mask 4 of the isolated person is not worn, and the display 14 is used to give an alarm, so that the worker can take measures to the isolated person in time, thereby reducing the risk of disease transmission.
Example 3
In this embodiment, the controller 9 of the mask 4 monitors the isolated person.
The respiratory airflow sensor 10 is a respiratory airflow sensor disclosed in patent document CN 205493782U, and the controller 9 of the mask 4 can know whether the mask 4 is worn or not in real time by using the respiratory airflow sensor 10, specifically: after the isolating person wears the mask 4, the breathing airflow sensor 10 is arranged on one side, facing the face, of the mask 4, so that the breathing airflow sensor 10 can acquire relevant signals of the breathing airflow of the isolating person in real time and send the relevant signals of the breathing airflow to the controller 9, and the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the relevant signals of the breathing airflow; after the mask 4 is taken off by the isolation person, the respiratory airflow sensor 10 cannot acquire a relevant signal of the respiratory airflow of the isolation person, and the controller 9 accordingly learns that the mask 4 is not worn by the isolation person in real time.
Respiratory airflow sensor 10 can be replaced by a temperature sensor, and controller 9 can utilize the temperature sensor to know in real time whether gauze mask 4 is worn by the isolated person, specifically: after the mask 4 is worn by the isolation person, the temperature sensor can detect the temperature of the exhaled air of the isolation person in real time or the skin temperature of the isolation person in real time and send corresponding temperature data to the controller 9, and the controller 9 can know that the mask 4 is worn by the isolated person in real time according to the corresponding temperature data; after the mask 4 is picked off by the isolating person, the temperature sensor cannot detect the temperature of the gas exhaled by the isolating person and cannot detect the skin temperature of the isolating person, so that the temperature data sent to the controller 9 by the temperature sensor becomes lower obviously, and the controller 9 learns that the mask 4 is not worn by the isolating person in real time.
People usually carry the portable electronic device 6 with them, so the location information of the portable electronic device 6 can be used as the location information of the isolated person who binds the portable electronic device 6.
When the monitoring system of the isolation personnel operates, the controller 7 of the portable electronic equipment 6 utilizes the positioning module 5 to position the position information of the portable electronic equipment 6 in real time, the controller 9 of the mask 4 acquires the position information of the portable electronic equipment 6 in real time through the network, namely, the position information of the isolation personnel is acquired in real time, and whether the isolation personnel is located in an isolation area or not is known in real time according to the position information, specifically: if the person in the isolation area is known to be located in the isolation area, the person in the isolation area does not leave the isolation area, and therefore the person in the isolation area does not need to wear the mask 4; if the isolation personnel is not located in the isolation area, the isolation personnel is away from the isolation area, so the isolation personnel needs to wear the mask 4 to reduce the risk of disease transmission. Therefore, after knowing that the isolated person leaves the isolated area, the controller 9 of the mask 4 also knows whether the mask 4 is worn or not in real time by using the respiratory airflow sensor 10, specifically: if the mask 4 is not worn, it means that the isolated person leaves the isolated area and does not wear the mask 4, which poses a greater risk of disease transmission; if it is known that the mask 4 is worn, it means that the isolated person leaves the isolated area but wears the mask 4, which does not pose a great risk of disease transmission.
In this embodiment, each monitoring camera 3 is respectively arranged in a main street and a small street outside the isolation area, thereby forming an skynet monitoring system. Controller 9 of gauze mask 4 learns that this isolation personnel is not located the isolation region according to isolation personnel's positional information, and learns to bind this isolation personnel's gauze mask 4 and not worn the back, can call the peripheral surveillance camera 3 in this position according to this isolation personnel's positional information, utilizes this surveillance camera 3 to acquire this isolation personnel's face state image, learns this gauze mask 4 according to this face state image in real time whether actually is worn again: if the mask 4 is not worn actually, it means that the mask 4 may be picked up by an isolated person, which causes a large risk of disease transmission, so that the controller 9 of the mask 4 sends an alarm to the controller 12 of the control center 1 through the network, and the controller 12 of the control center 1 displays the alarm to a worker through the display 14 after receiving the alarm, so that the worker can take measures in time, thereby reducing the risk of disease transmission; if it is known that the mask 4 is actually worn, it means that there may be an accident that may cause the respiratory airflow sensor 10 to not accurately detect whether the mask 4 is worn, for example, the respiratory airflow sensor 10 is damaged or an isolated person wears another mask, which does not cause a great risk of disease transmission, so the controller 9 of the mask 4 does not give an alarm.
Under the above-mentioned circumstances of knowing that gauze mask 4 is worn in fact, still other unexpected circumstances can lead to breathing airflow sensor 10 and can not detect out accurately whether gauze mask 4 is worn, for example, the isolation personnel stops breathing, controller 9 of gauze mask 4 should send out the police dispatch newspaper under this kind of unexpected circumstances so that the staff can in time make the measure of suing and labouring to this isolation personnel, consequently, after knowing that gauze mask 4 is worn in fact, controller 9 of gauze mask 4 utilizes surveillance camera 3 discernment this isolation personnel's action gesture through the network, controller 9 of gauze mask 4 can know whether this isolation personnel tumbles according to this isolation personnel's action gesture: if the isolated person is not fallen, the respiratory airflow sensor 10 is damaged, and the controller 9 of the mask 4 does not give an alarm; if the person in the isolation area falls down, the person in the isolation area may stop breathing, so the controller 9 of the mask 4 sends an alarm to the controller 12 of the control center 1 through the network, and the controller 12 of the control center 1 displays the alarm to the worker through the display 14 after receiving the alarm, so that the worker can take rescue measures for the person in the isolation area in time. It is conventional technology to identify the behavior posture of a person by using the monitoring camera 3 and judge whether the person falls down according to the behavior posture of the person, and the details are not repeated herein.
Non-preferably, be equipped with orientation module on gauze mask 4, this orientation module connects controller 9 of gauze mask 4, then controller 9 of gauze mask 4 can utilize this orientation module to fix a position out the positional information of gauze mask 4 as isolation personnel's positional information in real time, and isolation personnel monitored control system need not to set up portable electronic equipment 6 like this and also can acquire isolation personnel's positional information to learn whether isolation personnel are located the isolation region according to isolation personnel's positional information. Like this, if the isolation personnel do not carry gauze mask 4 when leaving the isolation region, then controller 9 of gauze mask 4 will misjudge that the isolation personnel still is located the isolation region to can not learn gauze mask 4 and not worn, the staff can not take measures to this isolation personnel yet, thereby can lead to having the disease to spread the risk. Considering that people usually carry the mobile phone or the portable electronic equipment 6 such as the positioning bracelet and the like when going out, the user can preferably acquire the position information of the isolation personnel in real time by utilizing the portable electronic equipment 6 such as the mobile phone or the positioning bracelet and the like to more accurately judge whether the isolation personnel is located in the isolation area, so that the user can timely know whether the mask 4 is worn or not to reduce the risk of disease propagation.
Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the protection scope of the present application, and although the present application is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present application without departing from the spirit and scope of the technical solutions of the present application.