CN117503088A - Watchband and user monitoring management system - Google Patents

Abstract

The invention discloses a watchband and a user monitoring and managing system, wherein the watchband comprises a band body, a circuit board and a blood pressure detecting unit, wherein the circuit board and the blood pressure detecting unit are arranged on the band body, the band body is detachably connected to a watch head, and the blood pressure detecting unit is electrically connected with the circuit board and used for detecting human blood pressure, so that the blood pressure of a user can be measured without configuring the watch head, the user can conveniently use the watchband, the user can replace the watch head, and the requirements of the user on different watch heads are met.

Description

Watchband and user monitoring management system

Technical Field

The invention relates to the technical field of wearing products, in particular to a watchband and a user monitoring management system.

Background

At present, an existing intelligent watch generally comprises a watch head and a watchband connected with the watch head, an air bag is generally required to be arranged on the watchband for blood pressure measurement, air, a circuit board and a pressure sensor are arranged on the watch head, the air pump is controlled by the circuit board in the watch head to drive the air pump to charge and discharge air for the air bag, the pressure sensor is used for sensing pressure change of an artery and transmitting a detected pressure value to the circuit board, and the circuit board is used for calculating blood pressure according to the pressure value. However, this method is dependent on the implementation of the watch head, and the effect of measuring blood pressure cannot be achieved after the watch head is replaced by the watch band.

Disclosure of Invention

The invention mainly aims to provide a watchband and a user monitoring management system, which are used for solving the problem that the existing intelligent watch can measure blood pressure only by matching a watch head with the watchband.

In order to solve the technical problems, the technical scheme provided by the invention is as follows:

a wristband, comprising:

the belt body is detachably connected to the watch head of the watch;

the circuit board is arranged on the belt body;

the blood pressure detection unit is arranged on the belt body and is electrically connected with the circuit board for detecting the blood pressure of the human body.

In one possible embodiment, the circuit board is a flexible circuit board, and the flexible circuit board is disposed in the belt body.

In one possible embodiment, the blood pressure detection unit employs a photoelectric sensor disposed on the belt body and electrically connected to the circuit board;

the photoelectric sensor generates pulse wave electric signals according to reflected light intensity fed back by blood fluctuation caused by heart beating of a human body and feeds the pulse wave electric signals back to the circuit board; the circuit board calculates the blood pressure value according to the pulse wave electric signal.

In one possible implementation, the blood pressure detection unit includes an air pump electrically connected to a circuit board, an air bag connected to the air pump, and a pressure sensor electrically connected to the circuit board; the air pump is arranged in the belt body, and the air bag is arranged along the length direction of the inner side wall of the belt body;

the air bag applies pressure to the wrist of a user when the air pump is driven to inflate, the pressure sensor is used for detecting the pressure value of the pulse of the user and generating pulse wave electric signals and amplitude change electric signals used for detecting the pressure value change generated in the inflation and deflation processes of the air bag, and the circuit board calculates the blood pressure value according to the pulse wave electric signals and the amplitude change electric signals.

In one possible embodiment, the wristband further comprises: and the battery is electrically connected with the circuit board and arranged in the belt body, and the wireless charging coil is used for supplying power to the circuit board.

In one possible embodiment, the band is provided with an adapter structure connected to the gauge outfit, the adapter structure being a mounting groove for placing the gauge outfit or a connecting piece connected to the gauge outfit.

In one possible implementation mode, the belt body is provided with a containing groove for containing medicines, and a cover body is arranged at the notch of the containing groove.

In one possible implementation manner, the watchband further comprises a physiological index acquisition unit electrically connected with the circuit board, wherein the physiological index acquisition unit is used for acquiring physiological indexes of a worn user in real time or periodically, and the physiological indexes comprise one or more of blood pressure values, heart rate values, blood oxygen, blood sugar, body temperature, blood fat, uric acid and exercise values.

In one possible implementation manner, the watchband further comprises a wireless transmission unit electrically connected with the circuit board and used for communicating with the mobile terminal, and the circuit board is used for uploading the blood pressure value acquired by the blood pressure detection unit and the physiological index acquired by the physiological index acquisition unit to the cloud end through the wireless transmission unit.

In one possible implementation mode, the watchband further comprises a shell for respectively installing a circuit board, a blood pressure detection unit, a wireless transmission unit, a physiological index acquisition unit, a battery and a wireless charging coil;

the shell is arranged on the outer side of the belt body; or the belt body or the inside of the belt body is provided with a groove, and the shell is arranged in the groove and is in interference fit with the groove.

In one possible implementation manner, the shell is provided with a wiring hole which is communicated with the inside and used for wiring, the belt body is provided with a plurality of wiring channels, and the wiring channels are respectively wiring wires electrically connected among the components of the circuit board, the blood pressure detection unit, the wireless transmission unit, the physiological index acquisition unit, the battery and the wireless charging coil;

the blood pressure detection unit comprises an air pump electrically connected with the circuit board, an air bag connected with the air pump and a pressure sensor electrically connected with the circuit board; the shell for installing the air pump is also provided with an air outlet and an air inlet which are connected with the air pump.

In one possible embodiment, the physiological index acquisition unit acquires a fall sensor including a sensor electrically connected to a circuit board and disposed within the belt body; the circuit board judges whether the user falls according to the electrical signal fed back by the falling sensor;

the circuit board is uploaded to the cloud through the wireless transmission unit when judging that the user falls down.

In one possible implementation manner, the watchband further comprises an alarm module electrically connected with the circuit board and arranged on the band body, wherein the alarm module is used for sending an alarm signal when the circuit board judges that the user falls down or the physiological index exceeds a threshold value.

In a possible embodiment, the watchband further comprises a positioning unit electrically connected to detect the position of the user, the positioning unit being arranged inside the band body;

and the circuit board uploads the position information positioned by the positioning unit to the terminal through the wireless transmission module when judging that the user falls down.

In one possible implementation manner, the physiological index acquisition unit acquires an acceleration sensor electrically connected with a circuit board, the acceleration sensor is arranged in the belt body, and the circuit board calculates a movement value according to an electric signal fed back by the acceleration sensor, wherein the movement value is one or more of the steps, the movement distance and the consumed heat.

In one possible embodiment, the watchband further comprises a heart rate sensor electrically connected with the circuit board and arranged in the band body, and the circuit board calculates the heart rate value according to the electric signal fed back by the heart rate sensor.

In one possible embodiment, the wristband further comprises a display electrically connected to the circuit board; the display is used for displaying the physiological index and the test value;

the watchband also comprises a switch piece which is electrically connected with the circuit board and is arranged on the band body; the circuit board is used for receiving the electric signals of the switch piece operated by a user and/or the electric signals operated by the APP end, and starting the detection function or switching the physiological index displayed by the display.

In one possible embodiment, the strap may be adjustable in length to suit different users' wrist widths.

On the other hand, the invention also provides a user monitoring management system, which comprises:

a wristband as described above;

the cloud end is used for receiving the physiological index transmitted by the wireless transmission module, monitoring the physiological index and transmitting a first alarm signal to the wireless transmission module when the physiological index exceeds a preset value;

the circuit board receives a first alarm signal fed back by the cloud through the wireless transmission module and sends out an alarm through the alarm module.

In one possible implementation manner, the user monitoring management system further comprises a monitoring terminal in communication with the cloud;

the cloud end is further used for sending a second alarm signal to the monitoring terminal when the physiological index continuously exceeds a preset value in a preset time period, and the monitoring terminal receives the second alarm signal and sends a reminding signal;

the cloud end is further used for transmitting an execution measurement signal to the watchband when a user operates, and the circuit board receives the execution measurement signal through the wireless transmission module to drive the blood pressure detection unit to work.

The invention has the following beneficial effects: compared with the prior art, the blood pressure measuring device has the advantages that the blood pressure is detected by arranging the circuit board and the blood pressure detecting unit on the watchband, the blood pressure measurement can be realized for the user without arranging the gauge outfit, the use is convenient for the user, the user can replace the gauge outfit, and the requirements of the user on different gauge outfits are met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a wristband according to an embodiment of the present invention used with a header;

FIG. 2 is a perspective view of a wristband according to an embodiment of the invention;

FIG. 3 is an exploded view of a wristband according to an embodiment of the invention in use with a header;

FIG. 4 is a perspective view of a first band in a wristband according to an embodiment of the invention;

FIG. 5 is a block diagram of a wristband according to another embodiment of the invention;

FIG. 6 is a block diagram of a wristband according to other embodiments of the invention;

FIG. 7 is a schematic block diagram of a user monitoring management system according to an embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-6, a wristband 10 is shown in accordance with an embodiment of the present invention.

The watchband 10 comprises a band body 1, a circuit board 3 and a blood pressure detection unit 2, wherein the circuit board 3 and the blood pressure detection unit 2 are arranged on the band body 1, the band body 1 is detachably connected to a watch head 00, and the blood pressure detection unit 2 is electrically connected with the circuit board 3 and used for detecting human blood pressure.

In this embodiment, the circuit board 3 and the blood pressure detecting unit 2 are configured on the watchband 10 to detect blood pressure, so that the blood pressure measurement can be realized for the user without configuring the watch head 00, the user can conveniently use the blood pressure measuring device, the user can replace the watch head 00, the requirements of the user on different watch heads 00 are met, and the problem that the blood pressure measurement can be realized only by matching the watchband 10 with the watch head 00 in the intelligent watch in the prior art is solved.

In one possible embodiment, the circuit board 3 is a flexible circuit board 3, and the flexible circuit board 3 is disposed in the belt body 1. The flexible circuit board 3 has flexibility and can be bent to adapt to the watchband 10, so that when the watchband 10 is fixed on the wrist of a user, the circuit board 3 does not influence the use of the watchband 10, and the watchband 10 can be attached to the wrist, so that the blood pressure detection unit 2 can be attached to the wrist of the user, and the blood pressure of the user can be measured better.

To realize that the blood pressure detection unit 2 measures blood pressure, the blood pressure detection unit 2 may employ the following structure.

The first structure of the blood pressure detection unit 2: the blood pressure detecting unit 2 includes a photoelectric sensor 24 provided on the band body 1 and electrically connected to the circuit board 3, the photoelectric sensor 24 is aligned with an artery on the wrist when the wristband 10 is fixed on the wrist and blood pressure is measured, emitted light in the photoelectric sensor 24 is irradiated onto the artery, reflected light intensity which is fed back by fluctuation of blood in the artery due to heart beat of a human body is changed, the intensity of light is different at a receiving end in the photoelectric sensor 24 is caused, so as to generate a pulse wave electric signal, the pulse wave electric signal is fed back to the circuit board 3, and the circuit board 3 calculates a blood pressure value according to the pulse wave electric signal, so as to measure blood pressure. In practical application, through holes or light-transmitting materials are formed in the inner side wall of the belt body 1 at positions corresponding to the transmitting end and the receiving end of the photoelectric sensor 24, so that measurement of blood pressure is not affected.

The second structure of the blood pressure detection unit 2: the blood pressure detecting unit 2 employs a device including an air pump 23 electrically connected to the circuit board 3, an air bag 21 connected to the air pump 23, and a pressure sensor 22 electrically connected to the circuit board 3. The air pump 23 is provided in the belt body 1, and the air bag 21 is provided along the length of the inner side wall of the belt body 1. The air bag 21 applies pressure to the wrist of the user when the air pump 23 is driven to inflate, the pressure sensor 22 is used for detecting the pressure value of the pulse wave of the user and generating a pulse wave electric signal and detecting an amplitude change electric signal generated by the change of the pressure value in the inflation and deflation processes of the air bag 21, and the circuit board 3 calculates the blood pressure value according to the pulse wave electric signal and the amplitude change electric signal so as to realize the measurement of the blood pressure.

The air pump 23 is disposed in the belt body 1 and is disposed along the thickness direction of the belt body 1 or the length and width direction with the circuit board 3.

In one possible embodiment, the watchband 10 further includes a battery 5 electrically connected with the circuit board 3 and disposed in the band body 1, and a wireless charging coil 6, wherein the battery 5 is used for supplying power to the circuit board 3, and the battery 5 can be charged through the circuit board 3 by using the wireless charging coil 6 in combination with an existing smart watch wireless charger on the market. Of course, in other embodiments, the battery 5 may also be a disposable battery 5, non-rechargeable, etc. Alternatively, in the embodiment with battery 5, wristband 10 also includes a charging contact electrically connected to circuit board 3, which may also enable charging of battery 5 when the external adapter is in use.

In one possible embodiment, the band body 1 is provided with an adapting structure 13 connected with the gauge outfit 00, and the adapting structure 13 is an installation groove for placing the gauge outfit 00, as shown in fig. 1, so that the gauge outfit 00 can be detachably installed in the installation groove to fix the gauge outfit 00, specifically, the side wall of the installation groove is of a soft rubber structure, that is, the gauge outfit 00 can be wrapped and fixed when the gauge outfit 00 is placed in the installation groove, and the user can conveniently replace the gauge outfit 00 for use. In other embodiments, as shown in FIG. 2. The adapting structure 13 may also be a connecting piece for connecting the gauge outfit 00, specifically, two ends of the band body 1 are detachably fixed on the gauge outfit 00, so as to realize connection with the gauge outfit 00, realize replacement of the gauge outfit 00, and the like.

In one possible implementation manner, the belt body 1 is provided with a containing groove 14 for containing medicines, and a cover 141 is arranged at the notch of the containing groove 14 for containing some small-sized tablets, so that the use is convenient for users when going out.

In a possible embodiment, the watchband 10 further comprises a physiological index acquisition unit 8 electrically connected to the circuit board 3, wherein the physiological index acquisition unit 8 is configured to acquire, in real time or periodically, physiological indexes of a user to be worn, the physiological indexes including one or more of blood pressure value, heart rate value, blood oxygen, blood sugar, body temperature, blood fat, uric acid, and exercise value. The physiological index collection module is used for collecting one or more of the heart rate value, blood oxygen, blood sugar, body temperature, blood fat, uric acid and exercise value of the human body, so that the functionality and the practicality of the watchband 10 can be improved, and the watchband is convenient for a user to use.

In a possible embodiment, the watchband 10 further includes a wireless transmission unit 7 electrically connected with the circuit board 3 and used for communicating with the mobile terminal, the circuit board 3 is used for uploading the blood pressure value collected by the blood pressure detection unit 2 and the physiological index collected by the physiological index collection unit 8 to the cloud 20 through the wireless transmission unit 7, and the watchband is matched with the mobile terminal and used by the cloud 20, and monitoring can be achieved through the mobile terminal and the cloud 20. Specifically, the wireless transmission unit 7 may be a radio frequency module, such as a bluetooth module, a 2G module, a 3G module, a 4G module, a 5G module, a 2.4G module, and the like.

In the above embodiment, the circuit board 3 may be integrally injection molded with the tape body 1 or provided protruding on the tape body 1. Or, the belt body 1 is provided with grooves 15 corresponding to the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6, the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6 are arranged in the grooves 15 which are respectively matched, and a glue filling layer which is used for respectively wrapping the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6 is arranged in the grooves 15, so that the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6 can be fixed on the belt body 1. In another embodiment, the watchband 10 further comprises a housing 4 for respectively mounting the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5, the wireless charging coil 6; the housing 4 may be disposed on the outer side of the belt body 1, or the housing 4 may be disposed in the groove 15 and be in interference fit with the groove 15 to fix the housing 4, however, in other embodiments, the housing 4 may be engaged in the groove 15 to fix the housing 4, etc.

On the basis of sufficient thickness of the watchband 10, the flexible circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6 can be arranged up and down along the thickness direction of the watchband 10; alternatively, in order to reduce the thickness of the wristband 10, the blood pressure detecting unit 2, the wireless transmitting unit 7, the physiological index collecting unit 8, the battery 5, the wireless charging coil 6 may be provided along the width or length direction of the wristband 10, or the like.

In practical application, the casing 4 is provided with a wiring hole 41 which is communicated with the inside and used for wiring, the belt body 1 is provided with a plurality of wiring channels 17, and the wiring channels 17 are respectively wiring wires electrically connected among the components of the circuit board 3, the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6, so that the circuit board 3 is respectively electrically connected with the blood pressure detection unit 2, the wireless transmission unit 7, the physiological index acquisition unit 8, the battery 5 and the wireless charging coil 6 through the wiring wires.

And in the embodiment in which the blood pressure detecting unit 2 includes the air pump 23, the air bag 21 and the pressure sensor 22, the housing 4 for mounting the air pump 23 is further provided with an air outlet 151 and an air inlet 152 connected to the air pump 23 through an air pipe 231 so that the air pump 23 is connected to the air bag 21.

In one possible embodiment, the physiological index acquisition unit 8 acquires a fall sensor 81 that includes a fall sensor electrically connected to the circuit board 3 and disposed within the belt body 1. The circuit board 3 judges whether the user falls according to the electrical signal fed back by the falling sensor 81, and when the user falls, the circuit board 3 uploads the electrical signal to the cloud 20 through the wireless transmission unit 7, and the cloud 20 can inform the matched user, so that the user wearing the watchband 10 of the embodiment is informed of the falling information of the monitoring end, and the user of the monitoring end can perform processing.

In a possible embodiment, the wristband 10 further comprises an alarm module 31 electrically connected to the circuit board 3 and provided on the strap body 1, the alarm module 31 being configured to send an alarm signal to notify the surrounding person when the circuit board 3 determines that the user falls. The alarm module 31 is used for informing the user wearing the watchband 10 when the physiological index of the circuit board 3 exceeds the threshold value, so that the user can seek medical attention in time to avoid delay.

In one possible embodiment, wristband 10 further comprises a locating unit 32 electrically connected for detecting the position of the user, locating unit 32 being provided inside band 1. The circuit board 3 uploads the position information positioned by the positioning unit 32 to the terminal through the wireless transmission unit 7 when the user falls down, so that the user at the monitoring end can know the specific position of the user wearing the watchband 10 and can timely process the position information. Wherein the positioning unit 32 may be a GPS sensor or the like.

Specifically, in one possible embodiment, the physiological index acquisition unit 8 acquires an acceleration sensor 82 electrically connected to the circuit board 3, the acceleration sensor 82 is disposed in the belt body 1, and the circuit board 3 calculates a movement value according to an electrical signal fed back by the acceleration sensor 82, where the movement value may be a step number, a movement distance, consumed heat, etc., so that a user can know the movement value.

In a possible embodiment, the wristband 10 further comprises a heart rate sensor 83 electrically connected to the circuit board 3 and arranged inside the band 1, the circuit board 3 calculating heart rate values from the electrical signals fed back by the heart rate sensor 83, so that the user knows his heart rate.

In a possible embodiment, the wristband 10 further comprises a display 18 electrically connected to the circuit board 3, the display 18 being adapted to display the physiological index and the test value, wherein the test value may be position information or the like.

The watchband 10 further comprises a switch element 33 electrically connected with the circuit board 3 and arranged on the band body 1, wherein the circuit board 3 is used for receiving an electric signal of a user operating the switch element 33 and/or receiving an electric signal of an APP end operation, and starting a detection function or switching the physiological index displayed by the display 18.

In one possible embodiment, band 1 may be adjustable in length to accommodate different user wrist widths, improving the applicability of wristband 10. Specifically, the belt body 1 includes a first belt body 11 and a second belt body 12, the airbag 21 is fixedly arranged on the inner side wall of the first belt body 11, a plurality of equally spaced clamping grooves 33 are formed in the outer side wall of the first belt body 11, clamping blocks 121 are arranged on the inner side wall of the second belt body 12 at one end, close to the first belt body 11, of the protrusion, the clamping blocks 121 are arranged in the clamping grooves 33 so as to connect the first belt body 11 with the second belt body 12, and the clamping blocks 121 are arranged in different clamping grooves 33, so that the length of the belt body 1 can be adjusted. The clamping grooves 33 may be two rows and located at two sides of the circuit board 3, so as to prevent the thickness of the watchband 10 from being increased while improving the connection stability between the first band 11 and the second band 12.

The present embodiment also provides a user monitoring and managing system adapted to the watchband 10, so as to be used by a user, for example, the watchband 10 can be applied to the elderly living alone, and the remote children know the physiological index of the parents, so as to play a role in monitoring the health of the user of the watchband 10, and timely process the user when abnormality is found, thereby improving the health management of the elderly living alone.

Referring to fig. 7, the user monitoring and managing system includes the watchband 10 described above and the cloud 20 in communication with the watchband 10, where the cloud 20 is configured to receive the physiological index transmitted by the wireless transmission unit 7 and monitor the physiological index, and send a first alarm signal to the wireless transmission unit 7 when the physiological index exceeds a preset value, and the circuit board 3 receives the first alarm signal fed back by the cloud 20 through the wireless transmission unit 7 and sends an alarm through the alarm module 31, so that a user of the watchband 10 knows his own physical condition, and reserves a doctor to process in time. Specifically, the alarm module 31 may be an indicator light or a horn electrically connected to the circuit board 3.

In one possible implementation, the user monitoring management system further includes a monitoring terminal 30 in communication with the cloud 20. The cloud 20 is further configured to send a second alarm signal to the monitor terminal 30 when the physiological index continuously exceeds a preset value in a preset time period, the monitor terminal 30 receives the second alarm signal and sends a reminding signal, specifically, the monitor terminal 30 is a mobile phone, a computer, an intelligent watch, etc. at the monitor end, so that when the physiological index of the user of the watchband 10 is abnormal, an alarm is sent out through the terminal, and a reminding and preventable effect is achieved. The cloud 20 may be an APP, and the cloud 20 is further configured to transmit a measurement signal to the watchband 10 when the user operates the watchband 10, that is, the user operates the watchband 10 on the APP to transmit the measurement signal, and the circuit board 3 of the watchband 10 receives the measurement signal through the wireless transmission unit 7 to drive the blood pressure detection unit 2 to work, so that the user can operate and use the terminal conveniently.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, "and/or" throughout this document includes three schemes, taking a and/or B as an example, including a technical scheme, a technical scheme B, and a technical scheme that both a and B satisfy; in addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims (20)

1. A wristband, comprising:

the belt body is detachably connected to the watch head of the watch;

the circuit board is arranged on the belt body;

the blood pressure detection unit is arranged on the belt body and is electrically connected with the circuit board for detecting the blood pressure of the human body.

2. The wristband of claim 1, wherein the circuit board is a flexible circuit board, the flexible circuit board being disposed within the wristband.

3. The wristband according to claim 1, wherein the blood pressure detecting unit includes a photosensor provided on the band body and electrically connected to the circuit board;

the photoelectric sensor generates pulse wave electric signals according to reflected light intensity fed back by blood fluctuation caused by heart beating of a human body and feeds the pulse wave electric signals back to the circuit board; the circuit board calculates the blood pressure value according to the pulse wave electric signal.

4. The watchband of claim 1, wherein the blood pressure detection unit includes an air pump electrically connected to the circuit board, an air bladder connected to the air pump, and a pressure sensor electrically connected to the circuit board; the air pump is arranged in the belt body, and the air bag is arranged along the length direction of the inner side wall of the belt body;

the air bag applies pressure to the wrist of a user when the air pump is driven to inflate, the pressure sensor is used for detecting the pressure value of the pulse of the user and generating pulse wave electric signals and amplitude change electric signals used for detecting the pressure value change generated in the inflation and deflation processes of the air bag, and the circuit board calculates the blood pressure value according to the pulse wave electric signals and the amplitude change electric signals.

5. The wristband according to claim 1, further comprising: and the battery is electrically connected with the circuit board and arranged in the belt body, and the wireless charging coil is used for supplying power to the circuit board.

6. The watchband of claim 1, wherein the band body is provided with an adapting structure connected with the watch head, and the adapting structure is a mounting groove for placing the watch head or a connecting piece connected with the watch head.

7. The watchband according to claim 1, wherein the band body is provided with a containing groove for containing medicines, and a cover body is arranged at a notch of the containing groove.

8. The wristband of claim 5, further comprising a physiological index acquisition unit electrically connected to the circuit board, the physiological index acquisition unit configured to acquire, in real time or periodically, a physiological index of a worn user, the physiological index including one or more of a blood pressure value, a heart rate value, blood oxygen, blood glucose, body temperature, blood lipid, uric acid, and a movement value.

9. The watchband of claim 8, further comprising a wireless transmission unit electrically connected to the circuit board for communicating with the mobile terminal, wherein the circuit board is configured to upload the blood pressure value collected by the blood pressure detection unit and the physiological index collected by the physiological index collection unit to the cloud end through the wireless transmission unit.

10. The wristband according to claim 1, further comprising a housing for each of the mounting circuit board, the blood pressure detecting unit, the wireless transmission unit, the physiological index collecting unit, the battery, the wireless charging coil;

the shell is arranged on the outer side of the belt body; or the belt body or the inside of the belt body is provided with a groove, and the shell is arranged in the groove and is in interference fit with the groove.

11. The watchband according to claim 10, wherein the shell is provided with a wiring hole which is communicated with the inside and used for wiring, the band body is provided with a plurality of wiring channels, and the plurality of wiring channels are respectively wiring wires electrically connected among the components of the circuit board, the blood pressure detection unit, the wireless transmission unit, the physiological index acquisition unit, the battery and the wireless charging coil;

the blood pressure detection unit comprises an air pump electrically connected with the circuit board, an air bag connected with the air pump and a pressure sensor electrically connected with the circuit board; the shell for installing the air pump is also provided with an air outlet and an air inlet which are connected with the air pump.

12. The wristband according to claim 1, wherein the physiological index acquisition unit acquires a fall sensor including a fall sensor electrically connected to a circuit board and disposed in the band body; the circuit board judges whether the user falls according to the electrical signal fed back by the falling sensor;

the circuit board is uploaded to the cloud through the wireless transmission unit when judging that the user falls down.

13. The wristband of claim 12, further comprising an alarm module electrically connected to the circuit board and disposed on the strap, the alarm module configured to emit an alarm signal when the circuit board determines that the user falls or the physiological index exceeds a threshold.

14. The wristband of claim 13, further comprising a locating unit electrically connected for detecting a user's position, the locating unit disposed within the wristband;

and the circuit board uploads the position information positioned by the positioning unit to the terminal through the wireless transmission module when judging that the user falls down.

15. The watchband of claim 1, wherein the physiological index acquisition unit acquires an acceleration sensor electrically connected with a circuit board, the acceleration sensor is arranged in the watchband, and the circuit board calculates a movement value according to an electrical signal fed back by the acceleration sensor, wherein the movement value is one or more of a step number, a movement distance and consumed heat.

16. The wristband of claim 1, further comprising a heart rate sensor electrically connected to the circuit board and disposed within the wristband, the circuit board calculating heart rate values from electrical signals fed back by the heart rate sensor.

17. The wristband of claim 1, further comprising a display electrically connected to the circuit board; the display is used for displaying the physiological index and the test value;

the watchband also comprises a switch piece which is electrically connected with the circuit board and is arranged on the band body; the circuit board is used for receiving the electric signals of the switch piece operated by a user and/or the electric signals operated by the APP end, and starting the detection function or switching the physiological index displayed by the display.

18. The wristband according to claim 1, wherein the strap is adjustable in length to fit different users' wrist widths.

19. A user monitoring management system, comprising:

the wristband of claim 8;

the cloud end is used for receiving the physiological index transmitted by the wireless transmission module, monitoring the physiological index and transmitting a first alarm signal to the wireless transmission module when the physiological index exceeds a preset value;

the circuit board receives a first alarm signal fed back by the cloud through the wireless transmission module and sends out an alarm through the alarm module.

20. The user monitoring management system of claim 19, further comprising a monitoring terminal in communication with the cloud;

the cloud end is further used for sending a second alarm signal to the monitoring terminal when the physiological index continuously exceeds a preset value in a preset time period, and the monitoring terminal receives the second alarm signal and sends a reminding signal;

the cloud end is further used for transmitting an execution measurement signal to the watchband when a user operates, and the circuit board receives the execution measurement signal through the wireless transmission module to drive the blood pressure detection unit to work.