CN113311945A - Flexible wearing and remote sensing device, method and system for campus health monitoring management - Google Patents
Flexible wearing and remote sensing device, method and system for campus health monitoring management Download PDFInfo
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- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/011—Arrangements for interaction with the human body, e.g. for user immersion in virtual reality
- G06F3/015—Input arrangements based on nervous system activity detection, e.g. brain waves [EEG] detection, electromyograms [EMG] detection, electrodermal response detection
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- G06K—GRAPHICAL DATA READING; PRESENTATION OF DATA; RECORD CARRIERS; HANDLING RECORD CARRIERS
- G06K17/00—Methods or arrangements for effecting co-operative working between equipments covered by two or more of main groups G06K1/00 - G06K15/00, e.g. automatic card files incorporating conveying and reading operations
- G06K17/0022—Methods or arrangements for effecting co-operative working between equipments covered by two or more of main groups G06K1/00 - G06K15/00, e.g. automatic card files incorporating conveying and reading operations arrangements or provisious for transferring data to distant stations, e.g. from a sensing device
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Abstract
The application discloses flexible wearing and remote sensing device, method and system of campus health monitoring management, the campus health monitoring management system includes: flexible dress and remote sensing device, RFID cluster and management terminal. Flexible dress and remote sensing device includes: school uniform jacket, biological electricity electrode sensor, flexible wrist strap, son detain, box, type C interface that charges, bee calling organ, warning button, status indicator lamp, flexible cable, RFID electronic tags, NFC chip, system control unit, wireless transmission unit, rhythm of the heart collection module, temperature acquisition module, system power management unit, lithium cell charge and discharge management unit, electric quantity detection module and orientation module. The positioning method comprises the following steps: the RFID electronic tag actively sends electromagnetic waves in real time, the electromagnetic waves are close to the RFID reader-writer and send the electromagnetic waves containing student identity information, and the RFID reader-writer receives the information and sends the student information, time and position to the management terminal. This application is convenient for monitor location student.
Description
Technical Field
The application relates to the field of health monitoring management, in particular to a flexible wearing and remote sensing device, method and system for campus health monitoring management.
Background
With the continuous development and maturity of wireless communication and cloud computing technologies, the internet of things is widely applied to various industrial fields, such as smart campus creation. Under the era of the internet of things, the campus develops towards the direction of environment digitization and intelligent management, the informatization construction of the school is accelerated, and the quality and the efficiency of school management work are improved.
In the education and teaching activities implemented by schools, as well as in school houses and living facilities with management responsibilities of schools, the safety problems faced by students mainly include campus violence, unexpected drowning, sudden abnormal physical health and the like. Any safety accident can bring heavy mental injury and even property loss to students parents and teachers and students in schools. Particularly, under the background of global outbreak of new crown pneumonia epidemic situation, the campus personnel density is high, the personnel mobility is high, the campus health and safety management and control are very important, and once a campus safety event occurs, the life health and safety of teachers and students in the whole school are seriously influenced; the device system for realizing campus safety emergency management by monitoring students and tracing the trajectories of the students in the prior art is lacked. Therefore, the flexible wearable and remote sensing device, method and system for campus health monitoring management are provided for solving the problems.
Disclosure of Invention
The flexible wearing and remote sensing device, method and system for campus health monitoring management are provided in the embodiment and used for solving the problem that monitoring, tracking and positioning of campus students are lacked in the prior art.
According to an aspect of the application, a campus health monitoring management system is provided, including flexible dress and remote sensing device, RFID cluster and management terminal, dress and be connected with remote sensing device through RFID cluster and management terminal, and flexible dress is connected through G communication network between and remote sensing device and the management terminal, also be connected through G communication network between RFID cluster and the management terminal.
Further, the RFID cluster is composed of a plurality of RFID readers.
As a second aspect of the present application, a flexible wearable and remote sensing device for campus health monitoring management is provided, which includes a school uniform jacket, a bioelectric electrode sensor and a flexible wrist strap, wherein the bioelectric electrode sensor is mounted on both the inner side of the front surface of the school uniform jacket and the inner side of the back surface of the school uniform jacket; the system comprises a flexible wrist strap, and is characterized in that an RFID electronic tag, an NFC chip, a system control unit, a wireless transmission unit, a heart rate acquisition module, a temperature acquisition module, a system power supply management unit, a lithium battery charge and discharge management unit, an electric quantity detection module and a positioning module are arranged in the flexible wrist strap, the wireless transmission unit, the heart rate acquisition module, the temperature acquisition module, the system power supply management unit, the electric quantity detection module and the positioning module are electrically connected to the system control unit, a TypeC charging interface, a buzzer, an alarm button and a state indicator lamp are fixedly embedded and installed on the outer surface of the flexible wrist strap, the system power supply management unit is electrically connected with the lithium battery charge and discharge management unit, the lithium battery charge and discharge management unit is electrically connected with the TypeC charging interface, and the buzzer, the alarm button and the state indicator lamp are electrically connected to the system control unit; the bioelectrical electrode sensor is electrically connected to a system control unit. The flexible wrist strap is fixedly connected with a flexible cable, one end of the flexible cable is electrically connected with the bioelectricity electrode sensor, and the other end of the flexible cable is electrically connected to the system control unit.
Furthermore, the inboard fixed mounting of one end of flexible wrist strap has the son to detain, the equidistant fixed mounting of other end outside along length direction has a plurality of box.
Further, the system control unit adopts an ARM processor.
Furthermore, the wireless transmission unit and the positioning module form a communication positioning module.
Further, the heart rate acquisition module adopts a heart rate sensor.
Furthermore, the temperature acquisition module adopts a temperature and humidity sensor.
As a third aspect of the present application, a campus health monitoring management navigation positioning method is provided, where the positioning method includes the following steps:
firstly, setting a safety identification distance according to a cluster control task and an area, and selecting a corresponding working frequency of an RFID reader-writer;
secondly, the RFID electronic tag in the flexible wearing and remote sensing device actively sends electromagnetic waves in real time, when the distance between the student and the RFID reader-writer is smaller than the RFID coverage range, the RFID electronic tag in the flexible wearing and remote sensing device is activated, and the RFID electronic tag sends the electromagnetic waves containing the identity information of the student;
thirdly, the RFID reader receives the information and sends the student information, time and position to the communication module;
and fourthly, the communication module uploads the data to the management terminal through the G communication network.
According to the embodiment of the application, RFID is adopted for identification and positioning, and the communication positioning module is matched for further positioning, so that accurate positioning and non-inductive acquisition are realized, and indoor and outdoor comprehensive tracking and positioning are realized; meanwhile, automatic contactless card punching can be carried out, the flexible wearable remote sensing device is close to the RFID cluster, and automatic activation and identification can be carried out to realize automatic card punching attendance; the health data can be synchronously managed, real-time monitoring of a user is carried out through the flexible wearing and remote sensing device, body temperature and heart rate monitoring is carried out, and the body temperature and the heart rate are transmitted to the management terminal to realize monitoring; the NFC chip is arranged inside the flexible wearable remote sensing device, and can be excited when the static distance actively contacts the card reader, so that accurate personal consumption can be realized.
Drawings
In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.
FIG. 1 is a schematic diagram of a campus health monitoring management system according to an embodiment of the present application;
FIG. 2 is a schematic view of a flexible wearable and remote sensing device according to an embodiment of the present application;
FIG. 3 is a schematic view of a flexible wristband and bioelectrode sensor according to an embodiment of the present application;
FIG. 4 is a schematic diagram of a bioelectrode sensor arrangement according to an embodiment of the present application;
FIG. 5 is a block diagram of hardware modules of a flexible wearable and remote sensing device according to an embodiment of the present application;
FIG. 6 is a diagram of hardware selection and circuit connections for a flexible wearable and remote sensing device according to an embodiment of the present application.
In the figure: 1. flexible dress and remote sensing device, 101, school uniform jacket, 102, biological electricity electrode sensor, 103, flexible wrist strap, 104, the son is detained, 105, the box, 106, type C interface that charges, 107, bee calling organ, 108, the warning button, 109, status indicator, 110, flexible cable, 111, RFID electronic tags, 112, the NFC chip, 113, system control unit, 114, wireless transmission unit, 115, heart rate collection module, 116, temperature acquisition module, 117, system power management unit, 118, lithium cell charge and discharge management unit, 119, electric quantity detection module, 120, orientation module, 2, the RFID cluster, 3, management terminal.
Detailed Description
In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the application described herein may be used. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.
In this application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the present application and its embodiments, and are not used to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.
Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.
Furthermore, the terms "mounted," "disposed," "provided," "connected," and "sleeved" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.
It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.
The flexible wearing and remote sensing device in the embodiment can be used for being installed on various coats, for example, the following arc protective clothing with the detachable protective cap is provided in the embodiment, and the flexible wearing and remote sensing device in the embodiment can be used for the following protective clothing to perform real-time monitoring on a human body.
An electric arc protective garment with a detachable protective cap comprises an electric arc protective coat, an electric arc protective cap and a grid helmet; sleeves are arranged above two sides of the arc protection coat; a sheath collar is arranged at the top of the arc protection coat; the electric arc protective cap is arranged at the top of the electric arc protective coat; the front side and the rear side below the electric arc protective cap are provided with surface baffles; fork openings are formed in two sides of the surface block; an eyepiece is arranged above the middle part of the front side of the electric arc protective cap. Preferably, the grid helmet is disposed inside an arc protection helmet. Preferably, an inner cape fabric is arranged inside the surface shield below the arc protection cap; the inner cape fabric is arranged inside the electric arc protection coat. Preferably, the periphery of the inner cape fabric is provided with a lower felt chain; the inner part of the electric arc protection coat is provided with a felt chain; the lower felt chain is fixedly arranged on the upper felt chain. Preferably, the top of the arc protection cap is provided with a spacer bush; the inner part of the spacer bush is in threaded connection with a connecting rod; the top of the connecting rod is provided with a handle. Preferably, a binding belt is arranged below the grid helmet. Preferably, the bottom of the connecting rod is provided with a circular truncated cone; a boss is arranged at the middle position of the top of the grid helmet; a clamping groove is formed in the boss; the round platform rotating shaft is connected inside the clamping groove. Preferably, guide rods are arranged below two sides of the grid helmet in the horizontal direction; guide rails are arranged on two sides inside the arc protective cap; the guide rod is connected inside the guide rail in a sliding mode. When the electric arc protective coat is used, the electric arc protective coat is worn firstly, then the electric arc protective cap is worn, and when the electric arc protective cap is worn, inner cape fabrics are arranged inside the surface shield below the electric arc protective cap; the inner cape fabric is arranged inside the electric arc protection coat, and the inner cape fabric of the protective cap is placed inside the electric arc protection coat from the top sheath collar separating position; the periphery of the inner cape fabric is provided with a lower felt chain; the inner part of the electric arc protection coat is provided with a felt chain; the lower felt chain is fixedly arranged on the upper felt chain; the electric arc protective cap and the electric arc protective jacket are fixedly sealed through the action of the upper felt chain and the lower felt chain. The rear baffles are covered on the front side and the rear side of the outer part of the electric arc protection coat, and the fork openings are positioned in the middle. The binding bands are arranged below the grid helmet, when the electric arc protective cap is worn, the head of the electric arc protective cap is in contact with the grid helmet, and the grid helmet is fixed on the head of the electric arc protective cap through the binding bands below the grid helmet; finishing the primary wearing of the arc protective cap; the protective cap and the protective clothes can be detached, spliced and sealed, and the electric arc protective clothes are convenient to wear. Step two, when the eyepiece is adjusted, the top of the arc protection cap is provided with a spacer bush; the inner part of the spacer bush is in threaded connection with a connecting rod; the connecting rod top is provided with the handle, clockwise rotation connecting rod top's handle, and the connecting rod can move down along the spacer sleeve when clockwise rotating. The bottom of the connecting rod is provided with a round table; a boss is arranged at the middle position of the top of the grid helmet; a clamping groove is formed in the boss; the rotary shaft of the circular truncated cone is connected inside the clamping groove, the connecting rod rotates to drive the circular truncated cone to rotate inside the clamping groove, and the connecting rod moves downwards along with the trend of moving towards the inside through the grid helmet, so that the electric arc protective cap can be lifted, and the ocular lens is lifted when the electric arc protective cap is lifted; the eyepiece reduces when the antiport grip in the same way, through the height of rotating the adjustable net helmet of connecting rod to the safety goggles's of realization height has been solved and the safety goggles on the helmet is fixed state, and when the staff of different sizes dressed, the safety goggles can not adjust the problem of suitable observation position. Guide rods are arranged below two sides of the grid helmet in the horizontal direction; guide rails are arranged on two sides inside the arc protective cap; the guide rod is connected inside the guide rail in a sliding manner; when the grid helmet moves up and down, the guide rod can be driven to slide up and down in the guide rail, the guide rod slides up and down along the guide rail, the directional movement effect of the grid helmet is achieved, and the grid helmet cannot rotate; therefore, when the electric arc protective clothing rotates, the head can drive the electric arc protective hat and the ocular lens to rotate together through the grid helmet, the working personnel can turn around to observe objects on two sides, and the problems that the protective hat of the existing electric arc protective clothing cannot rotate, and only the front part can be observed when the electric arc protective clothing is worn, and the two sides cannot be observed by turning around are solved.
Of course, the present embodiment can also be used for coats and clothes with other structures. Here, details are not repeated, and the flexible wearing and remote sensing device, method, and system according to the embodiments of the present application are described below.
Referring to fig. 1, the campus health monitoring and management system comprises a flexible wearable and remote sensing device 1, an RFID cluster 2 and a management terminal 3, wherein the wearable and remote sensing device is connected with the management terminal 3 through the RFID cluster 2, the flexible wearable and remote sensing device 1 is connected with the management terminal 3 through a 4G communication network, and the RFID cluster 2 is also connected with the management terminal 3 through a 4G communication network; the RFID cluster 2 is composed of several RFID readers.
The flexible wearable remote sensing device 1 is used as an acquisition terminal, so that various physiological state data of students in the campus activity process can be accurately acquired in real time, and the RFID cluster and wireless communication technology are combined to realize multi-data storage, monitoring processing, statistics, analysis and evaluation and provide comprehensive health and safety emergency management; flexible dress is passed up rhythm of the heart, body temperature information to management terminal 3 regularly with remote sensing device 1 through 4G communication network, monitors, and flexible dress is close to the RFID cluster with remote sensing device 1, carries out identification, and the RFID cluster adopts a plurality of RFID to read the ware, distributes in the different positions in campus, can be used to noninductive, contactless punch the card, has carried out student's location again.
As shown in fig. 2 to 6, as a second aspect of the present application, a flexible wearing and remote sensing device for campus health monitoring and management is provided, which includes a school uniform jacket 101, a bioelectricity electrode sensor 102 and a flexible wrist strap 103, wherein the bioelectricity electrode sensor 102 is installed on both the front inner side of the school uniform jacket 101 and the back inner side of the school uniform jacket 101, so as to implement flexible wearing, and the bioelectricity electrode sensor 102 is disposed at a heart position for acquiring an electrocardiographic signal.
The inside of the flexible wrist strap 103 is provided with an RFID electronic tag 111, an NFC chip 112, a system control unit 113, a wireless transmission unit 114, a heart rate acquisition module 115, a temperature acquisition module 116, a system power management unit 117, a lithium battery charging and discharging management unit 118, an electric quantity detection module 119 and a positioning module 120, wherein the wireless transmission unit 114, the heart rate acquisition module 115, the temperature acquisition module 116, the system power management unit 117, the electric quantity detection module 119 and the positioning module 120 are electrically connected to the system control unit 113, a TypeC charging interface 106, a buzzer 107, an alarm key 108 and a status indicator lamp 109 are fixedly embedded on the outer surface of the flexible wrist strap 103, the system power management unit 117 is electrically connected with the lithium battery charging and discharging management unit 118, the lithium battery charging and discharging management unit 118 is electrically connected with the TypeC charging interface 106, the buzzer 107, the lithium battery charging and discharging management unit 118 are electrically connected with the TypeC charging interface 106, and the buzzer 107, The alarm button 108 and the status indicator lamp 109 are electrically connected to the system control unit 113, the bioelectrical electrode sensor 102 is electrically connected to a system control unit 113, the system control unit 113 employs an ARM processor, the wireless transmission unit 114 and the positioning module 120 form a communication positioning module, the heart rate acquisition module 115 adopts a heart rate sensor, the temperature acquisition module 116 adopts a temperature and humidity sensor, the bioelectricity electrode sensor 102, the heart rate acquisition module 115 and the temperature acquisition module 116 realize the sensing of the human body, acquire the temperature and heart rate data, through the processing of the system power management unit 117, the wireless transmission unit 114 performs 4G communication to transmit information, transmits the acquired data to the management terminal 3 at regular time, the information transmission is realized by matching the approach of the RFID cluster 2 and the RFID electronic tag 111, so that double monitoring is realized; the positioning module 120 is further provided to enable positioning of a user, the wireless transmission unit 114 performs 4G communication to transmit information, the positioning data is transmitted to the management terminal 3 at regular time, and information transmission is achieved in cooperation with the approach of the RFID cluster 2 and the RFID electronic tag 111, so that double positioning is achieved, and a lithium battery is further arranged inside the flexible wrist band 103 and used for power supply.
The buzzer 107 has an alarm reminding function, and reminds a user or people nearby the user, so that timely rescue is facilitated.
The bioelectricity electrode sensor 102 is used for acquiring electrocardiosignals, the physical sensors are a heart rate sensor and a temperature and humidity sensor, the acquired signals are subjected to preprocessing such as filtering, amplification, analog-to-digital conversion and the like and are transmitted to the ARM processor through an IIC protocol, the MCU processes the data, the processed data are transmitted to the communication positioning module through the UART bus, and then the communication positioning module transmits the data to the management terminal 3 through cellular network signals. The power supply part realizes the charge and discharge management of the lithium battery by a TP4059 chip, and the voltage input by the lithium battery is provided for a 3.3V digital power supply required by the system through a series of LDOs. Electric quantity information is gathered to electric quantity detection module 119, transmits to the ARM treater through the IIC agreement, and MCU judges data, if the electric quantity is less than a certain numerical value then through GPIO interface control state pilot lamp 109 scintillation. The MCU monitors the GPIO interface state of the alarm key 108 in real time, and if the state changes, the alarm information is transmitted to the communication positioning module through the UART bus to be sent. If the MCU judges that the body temperature abnormity or the heart rate abnormity reminding information is received, the buzzer 107 is controlled to alarm through the GPIO interface.
The flexible wrist strap 103 is fixedly connected with a flexible cable 110, one end of the flexible cable 110 is electrically connected with the bioelectrode sensor 102, and the other end of the flexible cable 110 is electrically connected with the system control unit 113, so that the connection between the bioelectrode sensor 102 and the system control unit 113 is realized, and the flexible cable is used for transmitting information.
The inboard fixed mounting of one end of flexible wrist strap 103 has son to detain 104, the equidistant fixed mounting of length direction has a plurality of box 105 along the other end outside of flexible wrist strap 103, can be convenient for wear in wrist department, is applicable to the wrist of different thicknesses, and the flexible wrist strap 103 of being convenient for carries out better contact with the wrist, and temperature acquisition module 116 and rhythm of the heart acquisition module 115 are located flexible wrist strap 103 inboardly, contact with the human body.
Having the NFC chip 112 integrated into the smart wristband can only be activated when the static distance actively contacts the reader, thus enabling accurate personal consumption.
The campus health monitoring management navigation positioning method comprises the following steps:
firstly, setting a safety identification distance according to a cluster control task and an area, and selecting a corresponding working frequency of an RFID reader-writer;
secondly, the RFID electronic tag 111 in the flexible wearing and remote sensing device 1 actively transmits electromagnetic waves in real time, when the distance between a student and an RFID reader-writer is smaller than the RFID coverage range, the RFID electronic tag 111 in the flexible wearing and remote sensing device 1 is activated, and the RFID electronic tag 111 transmits electromagnetic waves containing student identity information;
thirdly, the RFID reader receives the information and sends the student information, time and position to the communication module;
and fourthly, the communication module uploads the data to the management terminal 3 through a 4G communication network.
Based on the 4G positioning module, namely the communication positioning module, the positioning and the track tracking of outdoor scenes can be realized. For the positioning of indoor scenes, an RFID wireless radio frequency technology is adopted. The RFID technology is a technology for performing non-contact bidirectional communication using radio waves or micro energy to realize identification and data exchange. The passive RFID tag 111 obtains energy through an electromagnetic field of a reader/writer to be activated, and transmits information such as self-encoding through an antenna. An RFID reader is deployed in an indoor activity area of a student, actively sends electromagnetic waves, reads passive RFID tags in a coverage area, and sends the tags to a server through a TCP/IP protocol communication network to realize indoor positioning of the student.
It is well within the skill of those in the art to implement, without undue experimentation, the present application is not directed to software and process improvements, as they relate to circuits and electronic components and modules.
The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.
Claims (10)
1. Campus health monitoring management system, its characterized in that: including flexible dress and remote sensing device (1), RFID cluster (2) and management terminal (3), dress and be connected with management terminal (3) through RFID cluster (2) with remote sensing device, and flexible dress is connected through 4G communication network between with remote sensing device (1) and management terminal (3), also through 4G communication network connection between RFID cluster (2) and management terminal (3).
2. The campus health monitoring management system of claim 1, wherein: the RFID cluster (2) is composed of a plurality of RFID readers.
3. The campus health monitoring management system of claims 1-2 enabled to obtain flexible wearing and remote sensing devices for campus health monitoring management, wherein: the multifunctional school uniform jacket comprises a school uniform jacket (101), a bioelectricity electrode sensor (102) and a flexible wrist strap (103), wherein the bioelectricity electrode sensor (102) is arranged on the inner side of the front surface of the school uniform jacket (101) and the inner side of the back surface of the school uniform jacket (101);
an RFID electronic tag (111), an NFC chip (112), a system control unit (113), a wireless transmission unit (114), a heart rate acquisition module (115), a temperature acquisition module (116), a system power management unit (117), a lithium battery charging and discharging management unit (118), an electric quantity detection module (119) and a positioning module (120) are arranged inside the flexible wrist strap (103), the wireless transmission unit (114), the heart rate acquisition module (115), the temperature acquisition module (116), the system power management unit (117), the electric quantity detection module (119) and the positioning module (120) are electrically connected to the system control unit (113), a TypeC charging interface (106), a buzzer (107), an alarm key (108) and a state indicator lamp (109) are fixedly embedded on the outer surface of the flexible wrist strap (103), and the system power management unit (117) is electrically connected with the lithium battery charging and discharging management unit (118), the lithium battery charging and discharging management unit (118) is electrically connected with the TypeC charging interface (106), and the buzzer (107), the alarm key (108) and the state indicator lamp (109) are electrically connected to the system control unit (113);
the bioelectrical electrode sensor (102) is electrically connected to a system control unit (113).
4. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: a flexible cable (110) is fixedly connected to the flexible wrist strap (103), one end of the flexible cable (110) is electrically connected with the bioelectricity electrode sensor (102), and the other end of the flexible cable (110) is electrically connected to a system control unit (113).
5. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: the inner side of one end of the flexible wrist strap (103) is fixedly provided with a sub-buckle (104), and the outer side of the other end of the flexible wrist strap (103) is fixedly provided with a plurality of female buckles (105) at equal intervals along the length direction.
6. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: the system control unit (113) adopts an ARM processor.
7. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: the wireless transmission unit (114) and the positioning module (120) form a communication positioning module (120).
8. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: the heart rate acquisition module (115) adopts a heart rate sensor.
9. The flexible wearable and remote sensing device for campus health monitoring management of claim 3, wherein: the temperature acquisition module (116) adopts a temperature and humidity sensor.
10. The method for obtaining campus health monitoring management navigation positioning by the campus health monitoring management system according to claims 1-2, wherein: the positioning method comprises the following steps:
firstly, setting a safety identification distance according to a cluster control task and an area, and selecting a corresponding working frequency of an RFID reader-writer;
secondly, the RFID electronic tag (111) in the flexible wearing and remote sensing device (1) actively transmits electromagnetic waves in real time, when the distance between a student and an RFID reader-writer is smaller than the RFID coverage range, the RFID electronic tag (111) in the flexible wearing and remote sensing device (1) is activated, and the RFID electronic tag (111) transmits electromagnetic waves containing identity information of the student;
thirdly, the RFID reader receives the information and sends the student information, time and position to the communication module;
and fourthly, the communication module uploads the data to the management terminal (3) through a 4G communication network.
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