CN219021165U - Split type health monitoring equipment - Google Patents

Abstract

The utility model relates to split health monitoring equipment, which comprises a wearable sensing terminal and an external display; the wearable sensing terminal comprises a monitoring shell, a health sensor and an electric energy storage module which are arranged in the monitoring shell, and a first charging connector which is arranged in the monitoring shell and is electrically connected with an electric energy output end of the electric energy storage module; the external display comprises a display screen, a power supply output end and a second charging connector, wherein the power supply output end is electrically connected with a power supply end of the display screen, the second charging connector is matched with a first charging connector of the wearable sensing terminal, and the electric energy storage module of the wearable sensing terminal supplies power for the display screen of the external display when the second charging connector of the external display is electrically connected with the first charging connector of the wearable sensing terminal. The utility model can improve the endurance of the wearable sensing terminal, and can provide a display screen for the wearable sensing terminal to complete the display function according to the requirement, thereby improving the monitoring effect of the health monitoring equipment.

Description

Split type health monitoring equipment

Technical Field

The utility model relates to the technical field of health monitoring equipment, in particular to split type health monitoring equipment.

Background

Health monitoring is the regular observation or irregular investigation of the health status of a particular population or sample of populations and census. Health monitoring may take the form of daily health monitoring, health surveys, and specialty surveys. Health monitoring is a main way to obtain health related information, and can provide basic data and scientific basis for health risk evaluation.

The main functions of the current intelligent health monitoring products (such as intelligent health bracelets, intelligent health watches and the like) are data acquisition, analysis, report presentation and the like of personal daily health information, generally, intelligent wearing sensing terminals acquire user health data and present brief information on a screen, meanwhile, the wearing sensing terminals upload the data to a cloud (such as cloud platforms, monitoring terminals and mobile phones), and users view current and historical health data reports of guardianship through mobile phone APP or clients of login product manufacturers.

Wearing sensing terminals such as intelligent health bracelets and intelligent health watches of current health monitoring equipment generally adopt a small-size display screen with the self-contained to display health monitoring data of users. However, when the conventional wearable sensing terminal is actually applied, most of the electric energy of the battery is consumed by frequent opening of the display screen, and the conventional wearable sensing terminal is limited by the requirements of small size and light weight of the wearable sensing terminal, so that the conventional wearable sensing terminal has the problems of short endurance time and frequent charging. Therefore, how to design a health monitoring device capable of improving the endurance of a wearable sensing terminal is a technical problem to be solved.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to solve the technical problems that: how to provide a split type health monitoring equipment, can improve the duration of wearing sensing terminal to can provide the display screen for wearing sensing terminal as required and for it accomplish the display function, thereby can improve health monitoring equipment's monitoring effect.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a split health monitoring device comprises a wearable sensing terminal and an external display;

the wearable sensing terminal comprises a monitoring shell, a health sensor and an electric energy storage module which are arranged in the monitoring shell, and a first charging connector which is arranged in the monitoring shell and is electrically connected with an electric energy output end of the electric energy storage module;

the external display comprises a display screen, a power supply output end and a second charging connector, wherein the power supply output end is electrically connected with a power supply end of the display screen, the second charging connector is matched with a first charging connector of the wearable sensing terminal, and when the second charging connector of the external display is electrically connected with the first charging connector of the wearable sensing terminal, an electric energy storage module of the wearable sensing terminal supplies power for the display screen of the external display.

Preferably, a charging socket is arranged on one side of the monitoring shell facing the user during use, and the power supply output end of the first charging connector is electrically connected with the charging socket;

the display screen deviates from the charging plug of charging socket adaptation that is provided with on the one side of display screen, and the power supply input and the charging plug electricity of second charging connector are connected for charging plug on the display screen is pegged graft the cooperation with the charging socket on the monitoring casing, and the second charging connector is connected with first charging connector electricity.

Preferably, more than two first magnetic attraction positioning blocks are arranged on one side, facing to a user, of the monitoring shell when the monitoring shell is used, second magnetic attraction positioning blocks corresponding to the first magnetic attraction positioning blocks one by one are arranged on one side, facing away from the display surface, of the display screen, and when a charging plug on the display screen is in plug-in fit with a charging socket on the monitoring shell, the second magnetic attraction positioning blocks are attracted with the corresponding first magnetic attraction positioning blocks.

Preferably, the wearable sensing terminal further comprises two wristbands fixedly arranged on two sides of the monitoring shell respectively; the one end that keeps away from the monitoring casing on two wrist straps sets up the buckle spare that the cooperation was used respectively to the one end that monitoring casing was kept away from to two wrist straps can be fixed through the buckle spare joint.

Preferably, the wearable sensing terminal further comprises a solar panel arranged in the monitoring shell and electrically connected with the electric energy storage module.

Preferably, the wearable sensing terminal further comprises a first wireless charging coil arranged in the monitoring housing and electrically connected with the electric energy storage module.

Preferably, the wearable sensing terminal further comprises a vibration power generation module which is arranged in the monitoring shell and is electrically connected with the electric energy storage module at the electric energy output end.

Preferably, the vibration power generation module comprises a magnet sliding guide rail, magnet blocks which are arranged on the magnet sliding guide rail and can slide freely along the magnet sliding guide rail, and two induction coils which are respectively arranged on two sides of the magnet blocks and can generate electromagnetic induction with the magnet blocks when the magnet blocks slide along the magnet sliding guide rail; the electric energy output ends of the two induction coils are electrically connected with the electric energy input end of the electric energy storage module.

Preferably, the two ends of the magnet sliding guide rail are provided with magnet sliding limit springs.

Preferably, the side of the monitoring shell facing the user is a front surface, and the side facing away from the front surface is a back surface;

a solar energy sensing window is arranged in the middle of the front surface of the monitoring shell; one side of the back of the monitoring shell is provided with a first wireless charging induction area, and the other side far away from the first wireless charging induction area is provided with a sensor detection window;

the solar energy receiving surface of the solar energy generating plate corresponds to the position of the solar energy sensing window; the charging induction end of the first wireless charging coil corresponds to the position of the first wireless charging induction area; the detection end of the health sensor corresponds to the position of the detection window of the sensor.

Compared with the prior art, the split type health monitoring equipment has the following beneficial effects:

in this application, intelligent health monitoring equipment is including wearing sensing terminal and external display, on the one hand, wear and do not set up the display screen on the sensing terminal, and only set up the health sensor that is used for gathering user health data, wear the sensing terminal promptly and only need accomplish data acquisition work, the display screen need not frequently to open, has solved the problem that the duration that current wearing sensing terminal leads to because of the display screen energy consumption is high is short and need frequently charge, and then can improve wearing sensing terminal's duration. On the other hand, this application is when the user needs to use the display screen, can peg graft the second that connects external display in wearing the first joint that charges of sensing terminal, and electric energy storage module can be for the display screen power supply this moment, and the display screen can normally work this moment, and health monitoring equipment can install the display screen as required in order to possess the display function promptly. Therefore, the cruising ability of wearing sensing terminal can be improved to this application to can provide the display screen for wearing sensing terminal as required and for it accomplish the display function, thereby can improve health monitoring facilities's monitoring effect.

Drawings

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be described in further detail with reference to the accompanying drawings, in which:

FIG. 1 is a schematic diagram of a mounting structure of a wearable sensing terminal and an external display;

fig. 2 is a schematic structural diagram of the front surface of the wearable sensing terminal;

FIG. 3 is a schematic diagram of the structure of the back of the display;

fig. 4 and 5 are schematic structural views of a vibration power generation module;

FIGS. 6 and 7 are schematic views of the structure of the back of the wearable sensing terminal;

fig. 8 and 9 are schematic views of structures inside the wearable sensing terminal;

fig. 10 is a logic block diagram of a data display communication terminal;

fig. 11 and 12 are schematic views showing the structure of the front surface of the data display communication terminal;

fig. 13 is a schematic view showing a structure of a back surface of a data display communication terminal.

Reference numerals in the drawings of the specification include: the monitoring housing 1, the solar energy sensing window 11, the first wireless charging sensing area 12, the sensor detection window 13, the body temperature sensor metal contact 14, the wrist strap 15, the display 2, the charging plug 21, the second magnetic attraction positioning block 22, the charging socket 31, the first magnetic attraction positioning block 32, the health sensor 41, the electric energy storage module 42, the first communication module 5, the vibration power generation module 6, the magnet sliding guide 61, the magnet block 62, the induction coil 63, the magnet sliding limit spring 64, the terminal housing 7, the display window 71, the code scanning window 72, the horn window 73, the intercom window 74, the power charging interface 75, the energy storage battery module 8 and the second communication module 9.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of 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. It will be apparent that the embodiments described are some, but not all, of the embodiments of the present application. The components of the embodiments of the present application, which are generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present application, as provided in the accompanying drawings, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, based on the embodiments herein, which are within the scope of the protection of the present application, will be within the skill of one of ordinary skill in the art without undue effort.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. In the description of the present application, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships that are conventionally put in use of the inventive product, are merely for convenience of description of the present application and simplification of description, and do not indicate or imply that the apparatus or element to be referred to must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance. Furthermore, the terms "horizontal," "vertical," and the like do not denote a requirement that the component be absolutely horizontal or overhang, but rather may be slightly inclined. For example, "horizontal" merely means that its direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly tilted. In the description of the present application, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

The following is a further detailed description of the embodiments:

embodiment one:

in this embodiment, a split health monitoring device is disclosed.

As shown in fig. 1 and 2, the split health monitoring device comprises a wearable sensing terminal and an external display;

the wearable sensing terminal comprises a monitoring shell 1, a health sensor 41 and an electric energy storage module 42 which are arranged in the monitoring shell 1, and a first charging connector which is arranged in the monitoring shell 1 and is electrically connected with an electric energy output end of the electric energy storage module 42 at a power supply input end;

the external display comprises a display screen 2, and a power supply output end is electrically connected with a power supply end of the display screen 2 and is electrically connected with a second charging connector adapted to a first charging connector of the wearable sensing terminal, and when the second charging connector of the external display is electrically connected with the first charging connector of the wearable sensing terminal, the electric energy storage module 41 of the wearable sensing terminal can supply power for the display screen 2 of the external display.

In this embodiment, the wearable sensing terminal may further include a main control chip (MT 6381 all-in-one intelligent health SOC chip).

The health sensor 41 and the electric energy storage module 42 are selected from devices or components well known in the art, and no modifications are made to this part in the present application. The health sensor 41 includes an existing MAX30205 type body temperature sensor (medical grade), an SOC connection via an IIC interface, an AS7038RB type blood oxygen heart rate respiration sensor (medical grade), an SOC connection via an IIC interface, an MKB0705 type blood pressure pulse wave sensor, and an SOC connection via an IIC interface.

In this application, intelligent health monitoring equipment is including wearing sensing terminal and external display, on the one hand, wear and do not set up the display screen on the sensing terminal, and only set up the health sensor that is used for gathering user health data, wear the sensing terminal promptly and only need accomplish data acquisition work, the display screen need not frequently to open, has solved the problem that the duration that current wearing sensing terminal leads to because of the display screen energy consumption is high is short and need frequently charge, and then can improve wearing sensing terminal's duration. On the other hand, this application is when the user needs to use the display screen, can peg graft the second that connects external display in wearing the first joint that charges of sensing terminal, and electric energy storage module can be for the display screen power supply this moment, and the display screen can normally work this moment, and health monitoring equipment can install the display screen as required in order to possess the display function promptly. Therefore, the cruising ability of wearing sensing terminal can be improved to this application to can provide the display screen for wearing sensing terminal as required and for it accomplish the display function, thereby can improve health monitoring facilities's monitoring effect.

As shown in connection with fig. 2 and 3, a charging socket 31 is arranged on the side, facing the user, of the monitoring housing in use, and the power supply output end of the first charging connector is electrically connected with the charging socket 31;

the display screen 2 is provided with the charging plug 21 with charging socket 31 adaptation on the side that deviates from the display surface, and the power supply input and the charging plug electricity of second charging connector are connected for when charging plug 21 on the display screen 2 and the charging socket 31 on the monitoring casing 1 peg graft the cooperation, the second charging connector is connected with first charging connector electricity, in order to realize supplying power for the display screen 2 through electric energy storage module 42.

In other preferred embodiments, the charging socket may be an existing USB interface, the data input end of which is connected to the SOC, and the charging plug may be an existing USB plug, the data output end of which is connected to the display screen. When the USB plug is plugged with the USB interface, the electric energy storage module supplies power for the display screen, and the SOC can control the display screen to execute a display function.

According to the method, the second charging connector and the first charging connector are electrically connected in a plug-in matching mode of the charging plug and the charging socket, the stability of the electrical connection of the two connectors can be guaranteed in the plug-in matching mode, and accordingly the display function can be finished by the wearable sensing terminal. Simultaneously, this application will charge the socket setting and face user's one side when monitoring the casing use, set up charging plug in the one side that the display screen deviates from the display surface for the position overall arrangement through design charging socket and charging plug is convenient to be used for the use to the display screen, thereby can further improve health monitoring equipment's display effect.

In the specific implementation process, more than two first magnetic attraction positioning blocks 32 are arranged on one side, facing a user, of the monitoring shell when the monitoring shell is used, second magnetic attraction positioning blocks 22 which are in one-to-one correspondence with the first magnetic attraction positioning blocks 32 are arranged on one side, facing away from the display surface, of the display screen 2, and when the charging plug 21 on the display screen 2 is in plug-in fit with the charging jack 31 on the monitoring shell 1, the second magnetic attraction positioning blocks 22 are attracted with the corresponding first magnetic attraction positioning blocks 32.

In this embodiment, the first magnetic positioning block and the second magnetic positioning block are both existing magnets.

According to the method, the first magnetic attraction positioning block on the monitoring shell and the second magnetic attraction positioning block on the display screen can achieve position positioning when the charging plug is in plug-in fit with the charging socket, and further the second charging connector and the first charging connector can be better electrically connected by an auxiliary user, so that the display function can be achieved by the wearable sensing terminal. Simultaneously, the mode that this application was inhaled through magnetism can be firm fix the display screen of external display on wearing the sensing terminal to can further improve health monitoring equipment's display effect.

In the specific implementation process, the wearing sensing terminal comprises two wristbands 15 fixedly arranged on two sides of the monitoring shell 1 respectively; the two wristbands 15 are respectively provided with a clamping piece which is matched with the monitoring shell 1 at one end far away from the monitoring shell 2, and the two wristbands 15 are fixed at one end far away from the monitoring shell 2 through clamping pieces.

In this embodiment, the buckle parts used in cooperation and arranged on the two wristbands 15 are of an existing mature structure, and the present application does not make any improvement on the part, and specifically can refer to the buckle structure used on the knapsack.

Specifically, the wearable sensing terminal further comprises a solar power panel arranged in the monitoring shell 1 and electrically connected with the electric energy storage module 42, and a first wireless charging coil arranged in the monitoring shell 1 and electrically connected with the electric energy storage module 42.

In this embodiment, the solar power panel and the first wireless charging coil are devices or components that are used in the prior art, and this application does not make any improvement.

The application realizes wearing the sensing terminal through wrist strap 15 (wears on the wrist), can improve wearing the convenience that the sensing terminal is fixed, dismantles and use. Meanwhile, the solar power generation panel is arranged to supplement electric energy for the electric energy storage module 42, so that the cruising ability of the wearable sensing terminal can be further improved. In addition, the application sets up first wireless charging coil and charges for electric energy storage module 42, can improve the portability of wearing sensing terminal charging.

In a specific implementation process, the wearable sensing terminal further comprises a vibration power generation module 6 which is arranged in the monitoring shell 1 and is electrically connected with the electric energy storage module 42.

In this embodiment, the vibration power generation module 6 is selected from devices or components used in the prior art.

For example, in connection with fig. 4 and 5:

the vibration power generation module 6 includes a magnet slide rail 61, a magnet block 62 provided on the magnet slide rail 61 and capable of freely sliding along the magnet slide rail 61, and two induction coils 63 provided on both sides of the magnet block 62, respectively, and capable of generating electromagnetic induction with the magnet block 62 when the magnet block 62 slides along the magnet slide rail 61; the power output of the two induction coils 63 is electrically connected to the power input of the power storage module 42. Magnet sliding limit springs 64 are provided at both ends of the magnet sliding guide 61.

The vibration power generation module 6 is arranged to supplement electric energy for the electric energy storage module 42, so that electric energy can be generated in real time in the process of user activities, and the cruising ability of the wearable sensing terminal can be further improved. Meanwhile, the structure of the vibration power generation module 6 in the application can effectively generate electric energy in real time in the process of user activities, so that electric energy can be better supplemented for the electric energy storage module 42.

As shown in connection with fig. 1, 6 and 7:

the monitoring shell 1 is characterized in that one side facing a user when in use is a front surface, and one side facing away from the front surface is a back surface;

a solar energy sensing window 11 is arranged in the middle of the front surface of the monitoring shell 1; a first wireless charging induction area 12 is arranged on one side of the back surface of the monitoring shell 1, and a sensor detection window 13 is arranged on the other side far away from the first wireless charging induction area 12; the back of the monitoring housing 1 is also provided with a body temperature sensor metal contact 14.

As shown in connection with fig. 8 and 9:

the solar energy receiving surface of the solar energy generating plate corresponds to the position of the solar energy sensing window 11; the charging induction end of the first wireless charging coil corresponds to the position of the first wireless charging induction area 12; the detection end of the health sensor 41 corresponds to the position of the sensor detection window 13.

According to the solar energy power generation system, the solar energy sensing window 11, the first wireless charging sensing area 12 and the sensor detection window 13 are designed, so that the related functions of the solar energy power generation panel, the first wireless charging coil and the health sensor 41 can be better realized; and the position layout of each window and each region ensures that each part with different shapes and different sizes can be mutually compatible and reasonably arranged, thereby being beneficial to realizing the miniaturization of the whole structure of the wearable sensing terminal.

Embodiment two:

the embodiment discloses health monitoring equipment with a data display communication terminal.

The wearable sensing terminal further comprises a first communication module 5 in communication connection with the data output end of the health sensor 41;

the data display communication terminal is used for communicating with one or more than two wearable sensing terminals, and comprises a second communication module 9 which is in communication connection with the data output end of the first communication module 5 corresponding to the wearable sensing terminal and in communication connection with a remote data processing end network, and a display screen which is in communication connection with the data output end of the second communication module 9.

In this embodiment, communication may also be performed between wearing sensing terminals. The wearable sensing terminals and the data display communication terminal communicate through the existing 2.4G RF Mesh ad hoc network protocol. Compared with the single transmission path of the Bluetooth, WIFI and other schemes of the current product, the multipath transmission scheme of the Mesh network has better signal transmission reliability and lower signal transmission power consumption.

It should be noted that, the split health monitoring device in this embodiment is mainly applied to a scenario where (old) users such as a nursing home, a happy hospital or a hospital are concentrated, and the user does not need to view own health monitoring data on a wearable sensing terminal, but views own health monitoring data on a data display communication terminal set at a specific position.

In the application, the intelligent health monitoring equipment comprises the wearing sensing terminal and the data display communication terminal which are separately arranged, on one hand, the wearing sensing terminal is not provided with a display screen, but is only provided with the health sensor for collecting the health data of the user and the first communication module for communication, namely, the wearing sensing terminal only needs to complete the work of data collection and transmission, and the problems of short duration and frequent charging caused by frequent starting of the display screen of the existing wearing sensing terminal are solved, so that the duration of the wearing sensing terminal can be improved; on the other hand, the data display communication terminal is used for receiving the data acquired by the wearable sensing terminal and uploading the data to a remote data processing end (such as a cloud platform, a remote monitoring system and a mobile phone), and meanwhile, the data display communication terminal can receive the issued health monitoring data display information so as to display the health monitoring data through a display screen: firstly, the data display communication terminal can be placed at any position to display information, so that convenience of health monitoring data display can be guaranteed, secondly, the size of a display screen is not limited any more, more complete health monitoring data (such as health data monitoring reports and reports) can be displayed through the display screen with a large size, practicability of the health monitoring data display can be guaranteed, finally, the data display communication terminal can be communicated with a plurality of wearable sensing terminals, namely, health monitoring data of a plurality of users can be displayed in a time-sharing mode or in a selectable mode through the display screen, practicability of the health monitoring data display can be guaranteed, accordingly, using effects of intelligent health monitoring equipment can be improved, and using experience of the users can be improved.

As shown in fig. 10, the data display communication terminal includes a terminal housing 7, and a display screen, a code scanning camera, a speaker module, an energy storage battery module 8, a microphone module and a second communication module 9 which are disposed in the terminal housing 7.

In this embodiment, the data display communication terminal includes a main control chip (i.mx7ul ultra-low power consumption internet of things SOC chip).

The display screen, the code scanning camera, the loudspeaker module, the energy storage battery module 8, the microphone module and the second communication module 9 are devices or components which are used in the prior art in a mature mode, and the code scanning camera, the loudspeaker module, the energy storage battery module and the microphone module are not improved in this application. The second communication module 9 may be an existing WIFI communication module, a 4G communication module, and an RF communication module, which are connected to the SOC through USB, UART, SPI interfaces, respectively. The code scanning camera is connected into the SOC through the MIPI interface. The display screen is connected with the SOC through the LCD interface. The loudspeaker module and the microphone module are connected into the SOC through the audio input and output interfaces.

The data display communication terminal further comprises a second wireless charging coil which is arranged in the terminal shell 7 and the electric energy output end of which is electrically connected with the energy storage battery module 8.

The second wireless charging coil is arranged to charge the energy storage battery module 8, so that the portability of charging the data display communication terminal can be improved.

As shown in connection with fig. 11, 12, and 13:

the side of the terminal shell 7 facing the user is the front side, and the side facing away from the front side is the back side;

the side of the terminal housing 7 is provided with a power charging interface 75 of the energy storage battery module 8.

The front surface of the terminal shell 7 is provided with a display window 71, an intercom window 74, a code scanning window 72 and a loudspeaker window 73; the front and back surfaces of the terminal housing 7 are provided with second wireless charging areas;

the display surface of the display screen corresponds to the position of the display window 71; the code scanning end of the code scanning camera corresponds to the position of the code scanning window 72; the sound playing end of the horn module corresponds to the position of the horn window 73; the sound collection end of the microphone module corresponds to the position of the intercom window 74; the charging induction end of the second wireless charging coil corresponds to the position of the second wireless charging induction area.

According to the wireless charging system, the specific positions of the display window 71, the intercom window 74, the code scanning window 72, the horn window 73 and the second wireless charging area are designed, so that the related functions of the display screen, the code scanning camera, the horn module, the microphone module and the second wireless charging coil can be better realized; and the position layout of the windows and areas enables the components of different shapes and sizes to be compatible and reasonably arranged with each other.

It should be noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the technical solution, and those skilled in the art should understand that modifications and equivalents may be made to the technical solution of the present utility model without departing from the spirit and scope of the technical solution, and all such modifications and equivalents are included in the scope of the claims of the present utility model.

Claims (10)

1. A split type health monitoring device, characterized in that: the wearable sensing terminal comprises a wearable sensing terminal and an external display;

the wearable sensing terminal comprises a monitoring shell, a health sensor and an electric energy storage module which are arranged in the monitoring shell, and a first charging connector which is arranged in the monitoring shell and is electrically connected with an electric energy output end of the electric energy storage module;

the external display comprises a display screen, a power supply output end and a second charging connector, wherein the power supply output end is electrically connected with a power supply end of the display screen, the second charging connector is matched with a first charging connector of the wearable sensing terminal, and when the second charging connector of the external display is electrically connected with the first charging connector of the wearable sensing terminal, an electric energy storage module of the wearable sensing terminal supplies power for the display screen of the external display.

2. The split health monitoring device of claim 1, wherein: a charging socket is arranged on one side, facing a user, of the monitoring shell when the monitoring shell is in use, and a power supply output end of the first charging connector is electrically connected with the charging socket;

the display screen deviates from the charging plug of charging socket adaptation that is provided with on the one side of display screen, and the power supply input and the charging plug electricity of second charging connector are connected for charging plug on the display screen is pegged graft the cooperation with the charging socket on the monitoring casing, and the second charging connector is connected with first charging connector electricity.

3. The split health monitoring device of claim 2, wherein: the monitoring shell is provided with more than two first magnetism on one side towards the user when in use, the display screen is provided with the second magnetism that is in one-to-one correspondence with each first magnetism on one side away from the display surface and inhale the locating piece to when the charging plug on the display screen is pegged graft with the charging socket on the monitoring shell and is joined in marriage, each second magnetism is inhaled the locating piece and is inhaled the locating piece actuation with its first magnetism that corresponds.

4. The split health monitoring device of claim 1, wherein: the wearable sensing terminal also comprises two wristbands which are respectively and fixedly arranged at two sides of the monitoring shell; the one end that keeps away from the monitoring casing on two wrist straps sets up the buckle spare that the cooperation was used respectively to the one end that monitoring casing was kept away from to two wrist straps can be fixed through the buckle spare joint.

5. The split health monitoring device of claim 1, wherein: the wearable sensing terminal further comprises a solar power generation panel which is arranged in the monitoring shell and is electrically connected with the electric energy storage module.

6. The split health monitoring device as set forth in claim 5, wherein: the wearable sensing terminal further comprises a first wireless charging coil which is arranged in the monitoring shell and is electrically connected with the electric energy storage module through an electric energy output end.

7. The split health monitoring device as set forth in claim 5, wherein: the wearable sensing terminal further comprises a vibration power generation module which is arranged in the monitoring shell and is electrically connected with the electric energy storage module through an electric energy output end.

8. The split health monitoring device as set forth in claim 7, wherein: the vibration power generation module comprises a magnet sliding guide rail, magnet blocks which are arranged on the magnet sliding guide rail and can slide freely along the magnet sliding guide rail, and two induction coils which are respectively arranged on two sides of the magnet blocks and can generate electromagnetic induction with the magnet blocks when the magnet blocks slide along the magnet sliding guide rail; the electric energy output ends of the two induction coils are electrically connected with the electric energy input end of the electric energy storage module.

9. The split health monitoring device as set forth in claim 8, wherein: the two ends of the magnet sliding guide rail are provided with magnet sliding limit springs.

10. The split health monitoring device as set forth in claim 5, wherein: the monitoring shell is characterized in that one side facing a user when in use is a front surface, and one side facing away from the front surface is a back surface;

a solar energy sensing window is arranged in the middle of the front surface of the monitoring shell; one side of the back of the monitoring shell is provided with a first wireless charging induction area, and the other side far away from the first wireless charging induction area is provided with a sensor detection window;

the solar energy receiving surface of the solar energy generating plate corresponds to the position of the solar energy sensing window; the charging induction end of the first wireless charging coil corresponds to the position of the first wireless charging induction area; the detection end of the health sensor corresponds to the position of the detection window of the sensor.

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