WO2017107508A1

WO2017107508A1 - Tight-fitting garment used for monitoring health, and method for monitoring health

Info

Publication number: WO2017107508A1
Application number: PCT/CN2016/095257
Authority: WO
Inventors: 张贯京
Original assignee: 深圳市纳福信息技术有限公司
Priority date: 2015-12-26
Filing date: 2016-08-15
Publication date: 2017-06-29
Also published as: CN105433922A

Abstract

Provided are a tight-fitting garment (100) used for monitoring health, and a method for monitoring health. the tight-fitting garment (100) comprises a garment body (05), and a belt (01), breast pocket (03), cuff (02), and edge (04) arranged on the garment body (05). The belt (01) comprises a belt body (1), a belt head (2), and a belt buckle (3). In the health monitoring method, the voltage signal of the electrode (101) in the groove (10) the belt buckle (3) catches is measured by the voltage sensor (30) in the belt buckle (3), and the waist circumference data of the wearer is automatically measured; by means of a breathing sensor (22) in the belt head (2), breathing frequency is detected from the abdomen of the wearer; by means of a heartbeat sensor (103) in the breast pocket (03), heart rate data is measured from the chest of the wearer; by means of a blood pressure sensor (102) in the cuff (02), blood pressure data is measured from the arm of the wearer; the described measured physical-indication data are sent to a cloud health management platform by means of a communications unit (23) in the belt body (2). The tight-fitting garment (100) automatically measures physical-indication data of a wearer all at the same time, thereby effectively monitoring in real time the health conditions of the wearer.

Description

Instructions Title: Tightening clothing and health monitoring methods for health monitoring

[0001] The present invention relates to the field of health monitoring, and more particularly to a tight clothing and health monitoring method for health monitoring.

Background technique

[0002] In daily life, many people are always worried that they are too fat, especially the waistline. Some people pay special attention to the changes in waist circumference according to their own aesthetic and work needs. Others are concerned with exercise and weight loss and need to measure their waistline regularly. Generally, people need a tape measure to measure their waist circumference, but they cannot always bring the tape measure around, which is inconvenient for measurement. In addition, the wearer needs to use a soft ruler to manually measure his waistline data while measuring his own waist circumference, and manually read the measured waistline data from the tape by visual inspection. The measurement data is caused by the error in manually reading the data. Not accurate enough.

[0003] In the field of health management, in addition to the waistline data of the user's obesity, respiratory frequency, heart rate and blood pressure are important vital parameters for monitoring the health of the patient. In a conventional health monitoring system, these key parameters are measured by using different vitality monitoring devices and measuring the vital signs completely independently of each other and output to the health management platform. This conventional health monitoring system increases the cost of components and interfaces and increases the complexity of the health monitoring system. Sex.

[0004] As we all know, clothes are a necessity for people's lives, and they can be worn every moment, but the existing clothes are only warm or decorative, and do not have health monitoring functions. To this end, it is necessary to design a health monitoring tight clothing and health monitoring method, which can not only solve the above problems easily, but also effectively monitor the health of the user and improve people's quality of life.

technical problem

[0005] The main object of the present invention is to provide a tight clothing and health monitoring method for health monitoring, which aims to solve the problem that the existing health monitoring system cannot automatically measure the waist circumference data and needs to use different vital sign monitoring devices and measure the signs completely independently of each other. Data and output to issues on the health management platform of the remote health management center.

Problem solution Technical solution

[0006] In order to achieve the above object, the present invention provides a tight garment for health monitoring, the tight garment comprising a garment body and a waistband, a breast pocket and a edging provided on the garment body, the waistband comprising a waistband body, a waistband head and a belt buckle, the inner side of the belt body is provided with a card slot having a unique size number every same preset distance, and each card slot is provided with an electrode of different resistance value, and the electrodes in each card slot pass a wire embedded in the waistband body is arranged in series, a voltage sensor is disposed inside the waistband buckle, the waistband includes a switch button, a microcontroller, a communication unit and a micro battery, and the chest pocket is provided with an electrocardiogram a sensor, the ECG sensor being coupled to the microcontroller via a flexible wire within the rim, wherein:

[0007] the microcontroller is configured to receive, by the communication unit, an initiating command sent by a cloud health management platform set in a health management center, and use the initiating command to enable the switch button to be used by the micro battery Powering the electrodes in each card slot;

[0008] The voltage sensor is configured to measure a voltage signal output by an inner electrode of a card slot that is caught by the belt buckle

And outputting a voltage signal of the electrode in the card slot to the microcontroller;

[0009] The microcontroller is further configured to identify a size number of the card slot corresponding to the electrode according to a voltage signal outputted by the inner electrode of the card slot that is caught by the belt buckle, and calculate the wearable according to the size number of the card slot. Waist circumference data;

[0010] the electrocardiographic sensor is configured to measure heart rate data of the wearer from the chest of the wearer, and send the heart rate data of the wearer to the microcontroller through a flexible wire within the rim;

[0011] The microcontroller is further configured to send the wearer's waistline data and heart rate data to the cloud health management platform through the communication unit.

[0012] Preferably, the waistband head further includes a breathing sensor for detecting a respiratory frequency of the wearer from the wearer's abdomen, and transmitting the wearer's respiratory frequency to the micro-control Device.

[0013] Preferably, the garment body is further provided with a cuff, wherein the cuff is provided with a blood pressure sensor for measuring blood pressure data of the wearer from the arm portion of the wearer, and the wearable The blood pressure data is sent to the microcontroller via a flexible wire within the rim.

[0014] Preferably, the microcontroller is further configured to send the wearer's respiratory frequency and blood pressure data to the cloud health management platform through the communication unit. [0015] Preferably, the waist belt, the cuff and the chest bag are formed into a joint structure by the hem, and are all disposed on the clothes body in a detachable structure.

[0016] In order to achieve the above object, the present invention provides a health monitoring method for use in a tight garment comprising a garment body and a waistband, a breast pocket and a edging provided on the garment body, the waistband including a waistband The body, the waistband and the belt buckle, the inner side of the waistband body is provided with a card slot having a unique size number every same preset distance, and each card slot is provided with an electrode of different resistance value, in each card slot The electrode is connected in series by a wire embedded in the waistband body, and a voltage sensor is disposed inside the waistband buckle, the waistband includes a switch button, a microcontroller, a communication unit and a micro battery, and the chest pocket is disposed An electrocardiographic sensor is coupled to the microcontroller via a flexible wire within the rim, the health monitoring method comprising the steps of:

[0017] the microcontroller receives, by the communication unit, an initiating command sent by the cloud health management platform set in the health management center, and the opening button is activated by the initiating button by the micro battery for each The electrodes in the card slot are powered;

[0018] The voltage sensor measures a voltage signal outputted by the inner electrode of the card slot that is caught by the belt buckle, and outputs a voltage signal of the electrode in the card slot to the microcontroller;

[0019] The microcontroller identifies the size number of the card slot corresponding to the electrode according to the voltage signal outputted by the inner electrode of the card slot that is caught by the belt buckle, and calculates the waist circumference data of the wearer according to the size number of the card slot; [0020] an electrocardiographic sensor measures heart rate data of the wearer from the chest of the wearer, and transmits the heart rate data of the wearer to the microcontroller through a flexible wire within the rim;

[0021] The microcontroller transmits the wearer's waistline data and heart rate data to the cloud health management platform via the communication unit.

[0022] Preferably, the waistband further includes a breathing sensor, the health monitoring method further comprising the steps of: the breathing sensor detecting a respiratory frequency of the wearer from the wearer's abdomen, and the wearer's The respiratory rate is sent to the microcontroller.

[0023] Preferably, the garment body is further provided with a cuff, wherein the cuff is provided with a blood pressure sensor, and the health monitoring method further comprises the steps of: the blood pressure sensor measuring the wearer's arm from the arm portion of the wearer Blood pressure data, and the wearer's blood pressure data is sent to the microcontroller through a flexible wire within the rim. [0024] Preferably, the health monitoring method further comprises the step of: the microcontroller transmitting the respiratory frequency and blood pressure data of the wearer to the cloud health management platform through the communication unit.

[0025] Preferably, the waist belt, the cuff and the chest pocket are each formed by the hem, and are disposed on the garment body in a detachable structure.

[0026].

Advantageous effects of the invention

Beneficial effect

[0027] Compared with the prior art, the present invention provides a tight clothing and health monitoring method for health monitoring, which can automatically measure physical data such as the wearer's waist data respiratory rate, blood pressure data, and heart rate data, and The physical condition data is sent to the cloud health management platform of the remote health monitoring center, so that the remote doctor can track and manage the health of the wearer.

Brief description of the drawing

DRAWINGS

1 is a schematic structural view of a preferred embodiment of a tight garment for health monitoring of the present invention;

2 is a front structural view of a preferred embodiment of a waistband for a tight-fitting garment for health monitoring according to the present invention; [0030] FIG. 3 is a schematic view showing the reverse structure of a preferred embodiment of a waistband for a tight-fitting garment of the present invention; 4 is a schematic diagram showing the internal structure of a preferred embodiment of a tight-fitting garment for health monitoring according to the present invention;

[0032] FIG. 5 is a flow chart of a preferred embodiment of the health monitoring method of the present invention.

[0033] The objects, features, and advantages of the present invention will be further described in conjunction with the embodiments.

BEST MODE FOR CARRYING OUT THE INVENTION

The specific embodiments, structures, features and utilities of the present invention are described in detail below with reference to the accompanying drawings and preferred embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

[0035] In order to achieve the object of the present invention, the present invention provides a tight-fitting garment for health monitoring, which can automatically measure physical data such as a wearer's waist circumference data respiratory rate, blood pressure data, and heart rate data, and can The physical condition data is sent to the cloud health management platform of the remote health monitoring center, so that the remote doctor can track and manage the health of the wearer.

[0036] As shown in FIG. 1, FIG. 1 is a schematic structural view of a preferred embodiment of a tight-fitting garment for health monitoring according to the present invention.

In the present embodiment, the tight garment 100 includes a garment body 05, a waistband 01, a cuff 02, a breast pocket 03, and a edging 04 disposed under the placket of the garment body 05. The rim 40 is embedded with a flexible wire, and the waistband 01, the cuff 02 and the chest pocket 03 are joined together to form a joint structure. The garment body 05 is made of a woven fabric of non-conductive fibers and has the characteristics of elasticity and softness, and enables the tight-fitting garment 100 to adhere to the wearer's skin while ensuring the wearer's comfortable type.

[0037] In order to ensure that the flexible wire can be energized, the waistband 01, the cuff 02 and the breast pocket 03 form a joint structure by the edging 04, and each is disposed on the garment body 05 in a detachable configuration. The detachable structure includes, but is not limited to, a snap, button, velcro, or other attachable structure. Therefore, when the tight-fitting garment 100 requires washing, the waistband 01, the cuff 02, the breast pocket 03, and the edging 04 can be detached from the garment body 05 to prevent the washing of the tight-fitting garment 100 to cause the belt 01, cuffs 02. The electrical components in the chest pocket 03 and the rim 04 were washed out and could not be used. When the wearer needs to wear the tight-fitting garment 100, the connected waistband 01, the cuff 02, the breast pocket 03, and the edging 04 are respectively attached to the garment body 05, so that it is convenient to use and is not washed. The impact has a strong practical value.

[0038]

As shown in FIG. 2, FIG. 2 is a front structural view of a preferred embodiment of the waist belt 01 of the tight-fitting garment for health monitoring of the present invention. In the present embodiment, the waist belt 01 includes a belt body 1, a waistband head 2, and a belt buckle 3, and the belt buckle 3 is disposed at a joint of the belt body 1 and the waistband 2. The waistband body 1 is made of the same material as the conventional plain waistband, and may be made of an insulating material such as soft leather or soft plastic. The outer casing of the waistband 2 and the belt buckle 3 are made of the same material as the conventional plain waistband and belt buckle, and may be made of an insulating material such as hard leather or hard plastic.

[0040]

[0041] As shown in FIG. 3, FIG. 3 is a schematic view showing the reverse structure of a preferred embodiment of the waist belt 01 of the tight-fitting garment for health monitoring of the present invention. In the present embodiment, the inside of the belt body 1 is provided with a card slot 10 having a unique size number every same preset distance (for example, 1 cm or 0.5 cm). In this embodiment, from the belt buckle 3 At the end of one end, a card slot 10 is provided at every preset distance, and each card slot 10 has a unique size number. If the length of the waistband body 1 is 100 cm and one card slot 10 is provided for each lcm, the number of the first card slot 10 is 1, the number of the second card slot 10 is 2, the number of the third card slot 10 is 3, and finally One card slot 10 is numbered 100. Each of the card slots 10 includes an electrode 101 of a different resistance value, and the electrodes 101 in each of the card slots 10 are connected in series by wires embedded in the waist belt body 1. When the belt buckle 3 is caught in the different card slots 10, since the resistance values of the electrodes 101 in each of the card slots 10 are different, the voltage signals output from the electrodes 101 in each of the card slots 10 are different. In this embodiment, the voltage signal outputted by the electrode 101 in each card slot 10 is a small voltage (for example, a voltage not greater than lmv), so that it does not have any influence on the health of the wearer.

[0042] In the embodiment, the inner side of the belt buckle 3 is provided with a voltage sensor 30. When the belt buckle 3 is engaged with one of the card slots 10, the voltage sensor 30 is used for sensing. The voltage signal output from the electrode 101 in the stuck card slot 10.

[0043]

[0044] As shown in FIG. 4, FIG. 4 is a schematic view showing the internal structure of a preferred embodiment of the tight-fitting garment for health monitoring of the present invention. Referring to Figures 2 and 3 together, the garment body 01 of the tight-fitting garment 100 is provided with a belt 01, a cuff 02, and a chest pocket 03. The waist belt 01 includes a belt body 1, a belt head 2, and a belt buckle 3. A blood pressure sensor 102 is disposed in the cuff 02, and an electrocardiographic sensor 103 is disposed in the chest pocket 03. The waistband 2 includes a microcontroller 20, a slamming button 21, a respiration sensor 22, a communication unit 23, a microbattery 24, and a charging port 25. The switch button 21, the breathing sensor 22, the communication unit 23, and the micro battery 24 are all connected to the microcontroller 20. The microbattery 24 is also coupled to the electrodes 101 in each of the card slots 10 to provide power to the electrodes 101 in each of the card slots 10. A voltage sensor 30 within the belt buckle 3 is coupled to the microcontroller 20. Both the blood pressure sensor 102 and the electrocardiographic sensor 103 are coupled to the microcontroller 20 by flexible wires within the rim 04.

[0045] The microcontroller 20, the respiration sensor 22, the communication unit 23, and the micro battery 24 are all disposed inside the waistband 2. Referring to FIGS. 1 and 2, the switch button 21 and the charging port 25 are disposed on the outer side of the waistband head 2, and may be respectively disposed on both sides of the waistband head 2, or may be disposed on the same side.

[0046] When the slamming button 21 is turned on, the micro battery 24 energizes the electrode 101 in each of the card slots 10. Waist The lock button 3 catches one of the card slots 10A, and the voltage sensor 30 measures the voltage signal output from the electrode 101 in the card slot 10, and transmits the voltage signal output from the electrode 101 to the microcontroller 20.

[0047] In this embodiment, the microcontroller 20 is a micro control unit (MCU), a data processing chip, or an information processing unit having a data processing function. The microcontroller 20 identifies the size number of the card slot 10 corresponding to the electrode 101 according to the voltage signal output from the electrode 101, and obtains the wearer's waistline data according to the size number of the card slot 10.

[0048] The respiration sensor 22 is a micro-breath sensing device that senses human respiratory waves in the prior art, and the specific structure is not described in detail in the present invention. In this embodiment, when the wearer activates the button 21 吋, the breathing sensor 22 detects the wearer's breathing frequency from the wearer's abdomen, and sends the wearer's breathing frequency to the micro-control 20.

[0049] In the present embodiment, since the garment body 05 is made of a woven fabric having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the garment body 05 can make the blood pressure in the cuff 02 The sensor 102 fits snugly against the wearer's arm. The blood pressure sensor 102 is a micro blood pressure sensing device for measuring blood pressure of a human body in the prior art, and the specific structure is not described in detail in the present invention. In this embodiment, when the wearer activates the button 21, the blood pressure sensor 102 measures the blood pressure data of the wearer from the arm portion of the wearer, and passes the wearer's blood pressure data through the edging. A flexible wire within 04 is sent to the microcontroller 20.

[0050] In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the garment body 05 can make the inside of the chest pocket 03 The ECG sensor 103 fits snugly against the wearer's chest. The electrocardiographic sensor 103 is a miniature heart rate sensing device for measuring a human heart rate in the prior art, and the specific structure is not described in detail in the present invention. In the present embodiment, the ECG sensor 103 measures the wearer's heart rate data from the wearer's chest, and transmits the wearer's heart rate data to the micro-control through the flexible wire in the rim 04. 20.

[0051] The communication unit 23 is a wireless communication interface with wireless communication function (for example, a short-range communication interface such as Bluetooth or WIFI or a remote communication interface). The communication unit 23 transmits the wearer's waistline data, respiratory rate, blood pressure data, and heart rate data to the cloud health management platform installed in the health management center, so that the remote doctor can track and manage the wearer's health.

[0052] The micro battery 24 is used to supply electrical energy to all electrical components in the tight garment 100, the miniature The battery 24 is a low-radiation, low-power rechargeable lithium battery that does not affect the health of the wearer. The micro battery 24 is also connected to a charging port 25, which can be a USB interface or other standard battery charging interface, and the charging port 25 can be directly inserted into an external power source (such as a computer USB interface or a low voltage regulator). The micro battery 24 is charged, for example. When the power of the microbattery 24 is used up, the wearer can charge the microbattery 24 through the charging port 25, thereby extending the life cycle of the tight garment 100.

[0053]

[0054] In order to achieve the object of the present invention, the present invention also provides a health monitoring method, which is applied to tight clothes and can automatically measure physical data such as waistband data, respiratory rate, blood pressure data and heart rate data of the wearer, and can The physical condition data is sent to the cloud health management platform of the remote health monitoring center, so that the remote doctor can track and manage the health of the wearer.

[0055] As shown in FIG. 5, FIG. 5 is a flow chart of a preferred embodiment of the health monitoring method of the present invention. In the embodiment, the circuit temperature drift compensation method is applied to the tight garment 100 shown in FIG. 1. As shown in FIG. 4, the method includes the following steps S51 to S57.

[0056] Step S51, the microcontroller 20 receives the startup command sent by the cloud health management platform set in the health management center through the communication unit 23, and starts the waistband of the tight-fitting clothing 100 by the initiating command. The shut-off button 21 on the second battery is powered by the micro-battery for the electrode 101 in each of the card slots 10 on the waist belt body 1. In the present embodiment, the electric energy of the electrode 101 in each of the card slots 10 is supplied from the micro battery 24 of the waistband 2.

[0057] Step S52, the voltage sensor 30 in the belt buckle 3 measures the voltage signal outputted by the inner electrode 101 of the card slot stuck by the belt buckle 3, and the voltage signal of the electrode 101 in the card slot Output to the microcontroller 20. In the present embodiment, when the belt buckle 3 is caught in the different card slots 10, since the resistance values of the electrodes 101 in each of the card slots 10 are different, the voltage signals output from the electrodes 101 in each of the card slots 10 are different.

[0058] Step S53, the microcontroller 20 identifies the size number of the card slot 10 corresponding to the electrode 101 according to the voltage signal output by the electrode 101 stuck by the belt buckle 3, and according to the size code of the card slot 10. Calculate the wearer's waistline data. In the present embodiment, since the inside of the belt body 1 is provided with a card slot 10 having a unique size number every same preset distance (for example, 1 cm or 0.5 cm), the wearer can be calculated by identifying the size number of the card slot 10. Waist data. [0059] Step S54, the breathing sensor 22 detects the respiratory frequency of the wearer from the wearer's abdomen and transmits the wearer's respiratory frequency to the microcontroller 20.

[0060] Step S55, the blood pressure sensor 102 measures the blood pressure data of the wearer from the arm portion of the wearer, and sends the blood pressure data of the wearer to the micro control through the flexible wire in the edging 04. 2 0. In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight-fitting garment 100 on the body, and the blood pressure sensor 102 in the cuff 02 can be brought close to the wearer's arm. The wearer's blood pressure data is measured at the site.

[0061] Step S56, the ECG sensor 103 measures the heart rate data of the wearer from the chest of the wearer, and sends the heart rate data of the wearer to the micro control through the flexible wire in the rim 04 20. In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the ECG sensor 103 in the chest pocket 03 can be placed close to the wearer. The chest measures the heart rate data of the wearer.

[0062] Step S57, the microcontroller 20 transmits the wearer's waistline data, respiratory rate, heart rate data and blood pressure data to the cloud health management platform set in the health management center through the communication unit 23 in the waistband 2 .

[0063]

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the invention, and the equivalent structure or equivalent function changes made by the description of the present invention and the contents of the drawings, or directly or indirectly applied to other related The technical field is equally included in the scope of patent protection of the present invention.

Embodiments of the invention

The specific embodiments, structures, features and functions of the present invention are described in detail below with reference to the accompanying drawings and preferred embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

[0066] In order to achieve the object of the present invention, the present invention provides a tight-fitting garment for health monitoring, capable of automatically measuring physical data such as a wearer's waist data respiratory rate, blood pressure data, and heart rate data, and capable of displaying the physical signs. Data is sent to the cloud health management platform of the remote health monitoring center for remote access The doctor actually tracks and manages the health of the wearer.

1, FIG. 1 is a schematic structural view of a preferred embodiment of a tight-fitting garment for health monitoring according to the present invention.

[0068] In order to ensure that the flexible wire can be energized, the waistband 01, the cuff 02 and the breast pocket 03 form a joint structure by the edging 04, and each is disposed on the garment body 05 in a detachable configuration. The detachable structure includes, but is not limited to, a snap, button, velcro, or other attachable structure. Therefore, when the tight-fitting garment 100 requires washing, the waistband 01, the cuff 02, the breast pocket 03, and the edging 04 can be detached from the garment body 05 to prevent the washing of the tight-fitting garment 100 to cause the belt 01, cuffs 02. The electrical components in the chest pocket 03 and the rim 04 were washed out and could not be used. When the wearer needs to wear the tight-fitting garment 100, the connected waistband 01, the cuff 02, the breast pocket 03, and the edging 04 are respectively attached to the garment body 05, so that it is convenient to use and is not washed. The impact has a strong practical value.

[0069]

[0071]

[0072] As shown in FIG. 3, FIG. 3 is a schematic view showing the reverse structure of a preferred embodiment of the waist belt 01 of the tight-fitting garment for health monitoring of the present invention. In the present embodiment, the inside of the belt body 1 is provided with a card slot 10 having a unique size number every same preset distance (for example, 1 cm or 0.5 cm). In this embodiment, starting from one end of the belt buckle 3, a card slot 10 is provided at every preset distance, and each card slot 10 has a unique size code. number. If the length of the waistband body 1 is 100 cm and one card slot 10 is provided for each lcm, the number of the first card slot 10 is 1, the number of the second card slot 10 is 2, the number of the third card slot 10 is 3, and finally One card slot 10 is numbered 100. Each of the card slots 10 includes an electrode 101 of a different resistance value, and the electrodes 101 in each of the card slots 10 are connected in series by wires embedded in the waist belt body 1. When the belt buckle 3 is caught in the different card slots 10, since the resistance values of the electrodes 101 in each of the card slots 10 are different, the voltage signals output from the electrodes 101 in each of the card slots 10 are different. In this embodiment, the voltage signal outputted by the electrode 101 in each card slot 10 is a small voltage (for example, a voltage not greater than lmv), so that it does not have any influence on the health of the wearer.

[0073] In the embodiment, the inner side of the belt buckle 3 is provided with a voltage sensor 30. When the belt buckle 3 is engaged with one of the card slots 10, the voltage sensor 30 is used for sensing. The voltage signal output from the electrode 101 in the stuck card slot 10.

[0074]

[0075] As shown in FIG. 4, FIG. 4 is a schematic view showing the internal structure of a preferred embodiment of the tight-fitting garment for health monitoring of the present invention. Referring to Figures 2 and 3 together, the garment body 01 of the tight-fitting garment 100 is provided with a belt 01, a cuff 02, and a chest pocket 03. The waist belt 01 includes a belt body 1, a belt head 2, and a belt buckle 3. A blood pressure sensor 102 is disposed in the cuff 02, and an electrocardiographic sensor 103 is disposed in the chest pocket 03. The waistband 2 includes a microcontroller 20, a slamming button 21, a respiration sensor 22, a communication unit 23, a microbattery 24, and a charging port 25. The switch button 21, the breathing sensor 22, the communication unit 23, and the micro battery 24 are all connected to the microcontroller 20. The microbattery 24 is also coupled to the electrodes 101 in each of the card slots 10 to provide power to the electrodes 101 in each of the card slots 10. A voltage sensor 30 within the belt buckle 3 is coupled to the microcontroller 20. Both the blood pressure sensor 102 and the electrocardiographic sensor 103 are coupled to the microcontroller 20 by flexible wires within the rim 04.

[0076] The microcontroller 20, the respiration sensor 22, the communication unit 23, and the micro battery 24 are all disposed inside the waistband 2. Referring to FIGS. 1 and 2, the switch button 21 and the charging port 25 are disposed on the outer side of the waistband head 2, and may be respectively disposed on both sides of the waistband head 2, or may be disposed on the same side.

[0077] When the switch button 21 is turned on, the micro battery 24 energizes the electrode 101 in each of the card slots 10. When the belt buckle 3 catches one of the card slots 10吋, the voltage sensor 30 measures the output of the electrode 101 in the card slot 10. The voltage signal is sent to the microcontroller 20 for the voltage signal output by the electrode 101.

In the embodiment, the microcontroller 20 is a micro control unit (MCU), a data processing chip, or an information processing unit having a data processing function. The microcontroller 20 identifies the size number of the card slot 10 corresponding to the electrode 101 according to the voltage signal output from the electrode 101, and obtains the wearer's waistline data according to the size number of the card slot 10.

[0079] The respiration sensor 22 is a micro-breath sensing device that senses human respiratory waves in the prior art, and the specific structure is not described in detail in the present invention. In this embodiment, when the wearer activates the button 21 吋, the breathing sensor 22 detects the wearer's breathing frequency from the wearer's abdomen, and sends the wearer's breathing frequency to the micro-control 20.

[0080] In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the garment body 05 can make the blood pressure in the cuff 02 The sensor 102 fits snugly against the wearer's arm. The blood pressure sensor 102 is a micro blood pressure sensing device for measuring blood pressure of a human body in the prior art, and the specific structure is not described in detail in the present invention. In this embodiment, when the wearer activates the button 21, the blood pressure sensor 102 measures the blood pressure data of the wearer from the arm portion of the wearer, and passes the wearer's blood pressure data through the edging. A flexible wire within 04 is sent to the microcontroller 20.

[0081] In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the garment body 05 can make the inside of the chest pocket 03 The ECG sensor 103 fits snugly against the wearer's chest. The electrocardiographic sensor 103 is a miniature heart rate sensing device for measuring a human heart rate in the prior art, and the specific structure is not described in detail in the present invention. In the present embodiment, the ECG sensor 103 measures the wearer's heart rate data from the wearer's chest, and transmits the wearer's heart rate data to the micro-control through the flexible wire in the rim 04. 20.

[0082] The communication unit 23 is a wireless communication interface with wireless communication function (for example, a short-range communication interface such as Bluetooth or WIFI or a remote communication interface). The communication unit 23 transmits the wearer's waistline data, respiratory rate, blood pressure data, and heart rate data to the cloud health management platform installed in the health management center, so that the remote doctor can track and manage the wearer's health.

[0083] The micro battery 24 is used to supply electric energy to all electrical components in the tight clothing 100, and the micro battery 24 is a low-radiation, low-power rechargeable lithium battery, which is not for the wearer. Health brings shadow ring. The micro battery 24 is also connected to a charging port 25, which can be a USB interface or other standard battery charging interface, and the charging port 25 can be directly inserted into an external power source (such as a computer USB interface or a low voltage regulator). The micro battery 24 is charged, for example. When the power of the microbattery 24 is used up, the wearer can charge the microbattery 24 through the charging port 25, thereby extending the life cycle of the tight garment 100.

[0084]

[0085] In order to achieve the object of the present invention, the present invention also provides a health monitoring method, which is applied to tight clothes and can automatically measure physical data such as waist circumference data, respiratory rate, blood pressure data and heart rate data of the wearer, and can The physical condition data is sent to the cloud health management platform of the remote health monitoring center, so that the remote doctor can track and manage the health of the wearer.

[0086] As shown in FIG. 5, FIG. 5 is a flow chart of a preferred embodiment of the health monitoring method of the present invention. In the embodiment, the circuit temperature drift compensation method is applied to the tight garment 100 shown in FIG. 1. As shown in FIG. 4, the method includes the following steps S51 to S57.

[0087] Step S51, the microcontroller 20 receives the startup command sent by the cloud health management platform set in the health management center through the communication unit 23, and activates the waistband of the tight-fitting clothing 100 by the opening command. The shut-off button 21 on the second battery is powered by the micro-battery for the electrode 101 in each of the card slots 10 on the waist belt body 1. In the present embodiment, the electric energy of the electrode 101 in each of the card slots 10 is supplied from the micro battery 24 of the waistband 2.

[0088] Step S52, the voltage sensor 30 in the belt buckle 3 measures the voltage signal outputted by the inner electrode 101 of the card slot stuck by the belt buckle 3, and the voltage signal of the electrode 101 in the card slot Output to the microcontroller 20. In the present embodiment, when the belt buckle 3 is caught in the different card slots 10, since the resistance values of the electrodes 101 in each of the card slots 10 are different, the voltage signals output from the electrodes 101 in each of the card slots 10 are different.

[0089] Step S53, the microcontroller 20 identifies the size number of the card slot 10 corresponding to the electrode 101 according to the voltage signal output by the electrode 101 stuck by the belt buckle 3, and according to the size code of the card slot 10. Calculate the wearer's waistline data. In the present embodiment, since the inside of the belt body 1 is provided with a card slot 10 having a unique size number every same preset distance (for example, 1 cm or 0.5 cm), the wearer can be calculated by identifying the size number of the card slot 10. Waist data.

[0090] step S54, the breathing sensor 22 detects the respiratory frequency of the wearer from the wearer's abdomen, and The wearer's respiratory rate is sent to the microcontroller 20.

[0091] step S55, the blood pressure sensor 102 measures the blood pressure data of the wearer from the arm portion of the wearer, and sends the blood pressure data of the wearer to the micro control through the flexible wire in the rim 04 2 0. In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight-fitting garment 100 on the body, and the blood pressure sensor 102 in the cuff 02 can be brought close to the wearer's arm. The wearer's blood pressure data is measured at the site.

[0092] Step S56, the ECG sensor 103 measures the heart rate data of the wearer from the chest of the wearer, and sends the heart rate data of the wearer to the micro control through the flexible wire in the rim 04 20. In the present embodiment, since the garment body 05 is made of a textile having elasticity and flexibility, the wearer can wear the tight garment 100 on the body, and the ECG sensor 103 in the chest pocket 03 can be placed close to the wearer. The chest measures the heart rate data of the wearer.

[0093] Step S57, the microcontroller 20 transmits the wearer's waistline data, respiratory rate, heart rate data and blood pressure data to the cloud health management platform set in the health management center through the communication unit 23 in the waistband 2 .

[0094]

The above are only the preferred embodiments of the present invention, and are not intended to limit the scope of the invention, and the equivalent structure or equivalent function transformations made by the description of the present invention and the accompanying drawings, or directly or indirectly The technical field is equally included in the scope of patent protection of the present invention.

Industrial applicability

[0096] Compared with the prior art, the present invention provides a tight clothing and health monitoring method for health monitoring, which can automatically measure physical data such as the wearer's waist data respiratory rate, blood pressure data, and heart rate data, and The physical condition data is sent to the cloud health management platform of the remote health monitoring center, so that the remote doctor can track and manage the health of the wearer.

[0097]

Claims

Claim

[Claim 1] A tight garment for health monitoring, the tight garment comprising a garment body and a waistband, a breast pocket and a edging provided on the garment body, the waistband comprising a waistband body, a waistband and a belt buckle, The utility model is characterized in that: a card slot having a unique size number is arranged at the same preset distance inside the waist belt body, and each card slot is provided with an electrode with different resistance values, and the electrodes in each card slot are embedded in the belt a wire is connected in the body, a voltage sensor is disposed on the inner side of the waistband buckle, the waistband includes a switch button, a microcontroller, a communication unit and a micro battery, and the chest card is provided with an electrocardiographic sensor, An ECG sensor is connected to the microcontroller through a flexible wire in the rim, wherein: the microcontroller is configured to receive, by the communication unit, an instruction sent by a cloud health management platform set in a health management center And powering the electrode in each card slot by the micro battery by using the opening command to open the switch button;

The voltage sensor is configured to measure a voltage signal output by the inner electrode of the card slot that is caught by the belt buckle, and output a voltage signal of the electrode in the card slot to the microcontroller; the microcontroller The utility model is further configured to identify a size number of the card slot corresponding to the electrode according to a voltage signal outputted by the inner electrode of the card slot caught by the belt buckle, and calculate a waist circumference data of the wearer according to the size number of the card slot;

The electrocardiographic sensor is configured to measure a heart rate data of the wearer from a chest of the wearer, and transmit the heart rate data of the wearer to the micro controller through a flexible wire within the rim;

The microcontroller is further configured to send the wearer's waistline data and heart rate data to the cloud health management platform through the communication unit.

[Claim 2] The skinny garment for health monitoring according to claim 1, wherein the waistband further comprises a breathing sensor for detecting a wearer's skin from the wearer's abdomen Respiratory frequency, and transmitting the wearer's respiratory rate to the microcontroller

[Claim 3] The tight garment for health monitoring according to claim 2, wherein the garment body is further provided with a cuff, wherein the cuff is provided with a blood pressure sensor, the blood pressure sensor A blood pressure data for measuring a wearer's blood pressure from the wearer's arm portion and transmitting the wearer's blood pressure data to the microcontroller through a flexible wire within the rim.

[Claim 4] The tight garment for health monitoring according to claim 3, wherein the microcontroller is further configured to send the wearer's respiratory frequency and blood pressure data to the communication unit through the communication unit In the cloud health management platform.

[Claim 5] The skinny garment for health monitoring according to claim 3 or 4, wherein the waistband, the cuff, and the breast pocket are each formed by the rim, and are both detachable The structure is disposed on the garment body.

[Claim 6] A health monitoring method for use in a tight garment comprising a garment body and a waistband, a breast pocket and a edging provided on the garment body, the waistband comprising a waistband body, a waistband and a belt lock The buckle is characterized in that: a card slot having a unique size number is disposed at the same preset distance inside the waistband body, and each of the card slots is provided with an electrode with a different resistance value, and the electrodes in each card slot are inlaid through the socket. a wire is connected in series in the waistband body, a voltage sensor is disposed on the inner side of the waistband buckle, the waistband includes a switch button, a microcontroller, a communication unit and a micro battery, and the ECG sensor is disposed in the chest bag The ECG sensor is connected to the microcontroller through a flexible wire in the rim, wherein the health monitoring method comprises the following steps:

The micro controller receives, by the communication unit, an initiating command sent by the cloud health management platform set in the health management center, and the opening button is opened by the initiating button, and the micro battery is used in each card slot. Electrode supply;

The voltage sensor measures a voltage signal outputted by the inner electrode of the card slot stuck by the belt buckle, and outputs a voltage signal of the electrode inside the card slot to the microcontroller; the microcontroller is stuck according to the belt buckle The voltage signal outputted by the electrode in the card slot identifies the size number of the card slot corresponding to the electrode, and calculates the waist circumference data of the wearer according to the size number of the card slot;

An electrocardiographic sensor measures heart rate data of the wearer from the wearer's chest and transmits the wearer's heart rate data to the microcontroller through a flexible wire within the rim; the microcontroller places the wearer Waist data and heart rate data are sent through the communication unit Sent to the cloud health management platform.

[Claim 7] The health monitoring method according to claim 6, wherein the waistband further includes a breathing sensor, and the health monitoring method further comprises the steps of:

The breathing sensor detects a wearer's breathing rate from the wearer's abdomen and transmits the wearer's breathing frequency to the microcontroller.

[Claim 8] The health monitoring method according to claim 7, wherein the garment body is further provided with a cuff, and the cuff is provided with a blood pressure sensor, and the health monitoring method further comprises the steps of:

The blood pressure sensor measures blood pressure data of the wearer from the wearer's arm portion and transmits the wearer's blood pressure data to the microcontroller via a flexible wire within the rim.

[Claim 9] The health monitoring method according to claim 8, wherein the health monitoring method further comprises the steps of:

The microcontroller transmits the wearer's respiratory rate and blood pressure data to the cloud health management platform via the communication unit.

[Claim 10] The health monitoring method according to claim 8 or 9, wherein the waist belt, the cuff, and the breast pocket are each formed by the hem, and are all disposed in a detachable structure. On the body of the garment.