CN106894143B

CN106894143B - heating fabric, heating fabric system, and method for controlling heating based on physiological data

Info

Publication number: CN106894143B
Application number: CN201510946462.7A
Authority: CN
Inventors: 陈利军; 艾方
Original assignee: Beijing Chuangxin Aishangjia Technology Co Ltd
Current assignee: Beijing Chuangxin Aishangjia Technology Co Ltd
Priority date: 2015-12-18
Filing date: 2015-12-18
Publication date: 2019-12-17
Anticipated expiration: 2035-12-18
Also published as: CN106894143A

Abstract

the invention discloses a heating fabric, and mainly aims to provide a heating fabric which is reasonable in structure and can be quantitatively heated in different areas. The heating fabric comprises three layers of textile structures, wherein partial areas or all areas on the fabric are functional areas, a first textile structure layer of each functional area is radially provided with a plurality of graphene conductive fiber lines, a second textile structure layer of each functional area is provided with a plurality of graphene conductive fiber lines in a weft direction, an intermediate textile structure layer is arranged between the first textile structure layer and the second textile structure layer, and the graphene conductive fiber lines on the first textile structure layer and the graphene conductive fiber lines on the second textile structure layer are mutually insulated by the intermediate textile structure layer. The heating fabric is used as a cape and a waistband, so that different areas of the heating fabric can output different heat according to requirements.

Description

heating fabric, heating fabric system, and method for controlling heating based on physiological data

Technical Field

The invention relates to the technical field of wearing sensors, in particular to a heating fabric system and a method for controlling the heating state of a wearing object based on physiological data.

background

in cold winter, people need a series of heating products, such as heating shawl, heating blanket and the like, and the heating products sold in the market at present generally have an electric heating element sandwiched between two layers of insulating cloth, achieve the purpose of heating through the electric heating element, and have single function and no intellectualization. In addition, the heating element on the existing market is generally a metal resistance wire, and the metal resistance wire heats up, and the weight is heavy. With the development of the intelligent and light-weight wearing device, the existing heating product can not meet the requirement, and graphene is used as the thinnest material and the strongest tough material, so that the graphene is very suitable for being applied to heat-generating elements of the heating product.

disclosure of Invention

aiming at the problems, the invention provides the heating fabric which is reasonable in structure and high in heat production speed. A multifunctional heating fabric system and a method for controlling the heating state of a wearing article based on physiological data with high intelligence degree.

in order to achieve the purpose, the heating fabric comprises a three-layer textile structure, wherein partial or all areas on the fabric are functional areas, a first textile structure layer of each functional area is radially provided with a plurality of graphene conductive fiber lines, a second textile structure layer of each functional area is provided with a plurality of graphene conductive fiber lines in a weft direction, an intermediate textile structure layer is arranged between the first textile structure layer and the second textile structure layer, and the graphene conductive fiber lines on the first textile structure layer and the graphene conductive fiber lines on the second textile structure layer are mutually insulated by the intermediate textile structure layer.

The heating fabric system comprises the heating fabric, a time-sharing multiplexing switch, a controller, a temperature setting module, a heartbeat acquisition module, a body temperature acquisition module, a first pressure acquisition module, a second pressure acquisition module and/or a humidity acquisition module, wherein the temperature setting module, the heartbeat acquisition module, the body temperature acquisition module, the first pressure acquisition module, the second pressure acquisition module and/or the humidity acquisition module are/is connected with the controller in a wireless or wired mode;

the time-sharing multiplexing switch controls each graphene conductive fiber wire of each textile structure layer to be connected with or disconnected from a power supply according to the instruction of the controller;

the temperature setting module is connected with the graphene conductive fiber lines of the first textile structure layer and the second textile structure layer and is used for setting voltage values of the graphene conductive fiber lines of the first textile structure layer and the second textile structure layer;

the heartbeat collecting module is connected with at least one heartbeat collecting line group of the first textile structure layer and/or the second textile structure layer, each heartbeat collecting line group consists of any two graphene conductive fiber lines on the same textile structure layer, the heartbeat collecting module receives an instruction of the controller and collects a first resistance value between the two heartbeat collecting lines of each heartbeat collecting line group,

if the first resistance value is within the range of the dry resistance threshold value, acquiring the voltage between the two heartbeat acquisition lines,

if the voltage value is 0, sending alarm information;

if the voltage value is within the first voltage threshold range (a, b), outputting the voltage value to a controller;

If the voltage value is smaller than the second voltage threshold value, the controller sends out the starting of heating the first textile structure layer and/or the second textile structure layer until the voltage value is 0 or the voltage value is within the first voltage threshold value range (a, b);

if the first resistance value is within the range of the wet resistance, the controller sends out a starting state to heat the first textile structure layer and/or the second textile structure layer until the first resistance value between the two body temperature acquisition lines is within the range of the dry resistance threshold value;

the controller calculates the human heartbeat according to the received voltage value;

the body temperature acquisition module is connected with at least one group of body temperature acquisition line groups of the first textile structure layer and/or the second textile structure layer, each group of body temperature acquisition line group consists of any two graphene conductive fiber lines on the same textile structure layer and acquires a second resistance value between the two body temperature acquisition lines,

if the second resistance value is within the range of the dry resistance threshold value, alarm information is sent out;

if the second resistance value is within the first electric group threshold value range (c, d), outputting the second resistance value to the controller;

If the voltage value is within the moisture resistance threshold value, the controller sends out a starting operation to heat the first textile structure layer and/or the second textile structure layer until a second resistance value between the two body temperature acquisition lines is larger than the first threshold value or within a second electric group threshold value range (c, d);

The controller calculates the body temperature according to the received second resistance value;

the first pressure acquisition module is connected with the graphene conductive fiber line of the first textile structure layer through a plurality of first row data lines respectively, and is connected with the graphene conductive fiber line of the third textile structure layer through a plurality of first column data lines respectively, the first row data lines and the first column data lines form a chessboard structure, intersection points of the graphene conductive fiber lines of the first textile structure layer and the third textile structure layer are positioned, and the positioned intersection points are sent to the controller;

the second pressure acquisition module is connected with the graphene conductive fiber line of the fourth textile structure layer through a plurality of second row data lines respectively, and is connected with the graphene conductive fiber line of the fifth textile structure layer through a plurality of second line data lines respectively, the second row data lines and the second line data lines form a chessboard structure, intersection points of the graphene conductive fiber lines of the fourth textile structure layer and the fifth textile structure layer are positioned, and the positioned intersection points are sent to the controller;

the humidity acquisition module is connected with at least one group of humidity acquisition line groups of the first textile structure layer, the second textile structure layer, the third textile structure layer, the fourth textile structure layer and/or the fifth textile structure layer, each group of humidity acquisition line group consists of any two graphene conductive fiber lines of the first textile structure layer, the second textile structure layer, the third textile structure layer, the fourth textile structure layer and/or the fifth textile structure layer, and acquires a third resistance value between the two humidity acquisition lines,

If the third resistance value is within the dry threshold range, no processing is performed;

and if the third resistance value is within the humidity threshold range, sending the third resistance value to a controller, and calculating the humidity of the heating fabric by the controller according to the third resistance value.

to achieve the above object, the present invention provides a method for controlling a heating state of a wearing article based on physiological data, the method comprising:

A garment made using the above-described heated fabric or heated fabric system;

setting the resistance value between two graphene conductive fiber lines on the wearing object within a drying threshold range as a standard state of the wearing object;

in the normal state of the item of clothing,

Taking two graphene conductive fiber wires of a textile structure layer in contact with skin of a wearing object as a group, collecting voltage values of the skin at different parts of a human body, simultaneously collecting heartbeat values, and establishing a database corresponding to the voltage values of the skin of the human body and the heartbeat values, wherein the database comprises a standard voltage range (a1, b1) corresponding to normal heartbeat of the human body, a voltage range (a, a1) corresponding to too fast heartbeat and a voltage range (b1, b) corresponding to too slow heartbeat;

Taking two graphene conductive fiber wires of a textile structure layer in contact with skin of a wearing object as a group, collecting the resistance values of the skin of different parts of a human body, simultaneously collecting body temperature values, and establishing a database corresponding to the resistance values of the skin of the human body and the body temperature values, wherein the database comprises a standard voltage range (c1, d1) corresponding to normal body temperature of the human body, a voltage range (c, c1) corresponding to hypothermia and a voltage range (c1, d) corresponding to overhigh body temperature;

two graphene conductive fiber lines on the same textile structure layer are taken as heartbeat collecting lines, a first resistance value between the two heartbeat collecting lines is collected,

if the voltage value is 0, sending alarm information;

if the voltage value is smaller than the second voltage threshold value, starting to heat the first textile structure layer and/or the second textile structure layer until the voltage value is 0 or the voltage value is within a first voltage threshold value range (a, b);

If the first resistance value is within the range of the wet resistance, starting to heat the first textile structure layer and/or the second textile structure layer until the first resistance value between the two body temperature acquisition lines is within the range of the dry resistance threshold;

comparing the acquired voltage value with a standard voltage value range (a1, b1),

If the voltage value is within the standard voltage value range (a1, b1), maintaining the voltage of the graphene conductive fiber wires of the first textile structure layer and/or the second textile structure layer unchanged;

if the voltage value is greater than a and less than a1, increasing the voltage of the graphene conductive fiber lines of the first textile structure layer and/or the second textile structure layer at a preset frequency until the voltage value obtained by the controller reaches a standard voltage value range (a1, b1) or the voltage of the graphene conductive fiber lines of the first textile structure layer and/or the second textile structure layer reaches a maximum value;

if the voltage value is greater than b1 and less than b, reducing the voltage of the graphene conductive fiber lines of the first textile structure layer and/or the second textile structure layer at a preset frequency until the voltage value obtained by the controller reaches a standard voltage value range (a1, b1) or the voltage of the graphene conductive fiber lines of the first textile structure layer and/or the second textile structure layer reaches a minimum value;

Calculating the human heartbeat according to the received voltage value;

taking two graphene conductive fiber wires on the same textile structure layer as body temperature acquisition wires, acquiring a second resistance value between the two body temperature acquisition wires,

if the second resistance value is within the first electrical set threshold range (c, d), outputting the second resistance value;

If the voltage value is within the moisture resistance threshold value, starting to heat the first textile structure layer and/or the second textile structure layer until a second resistance value between the two body temperature acquisition lines is larger than the first threshold value or within a second electric group threshold value range (c, d);

comparing the acquired first resistance value with the standard resistance value range (c1, d1),

if the second resistance value is within the standard resistance value range (c1, d1), maintaining the voltage of the graphene conductive fiber wires of the first textile structure layer and/or the second textile structure layer unchanged;

If the second resistance value is larger than c and smaller than c1, increasing the voltage of the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer at a preset frequency until the second resistance value obtained by the controller reaches a standard resistance value range (c1, d1) or the voltage of the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer reaches a maximum value;

if the second resistance value is larger than d1 and smaller than d, reducing the voltage of the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer at a preset frequency until the second resistance value obtained by the controller reaches a standard resistance value range (c1, d1) or the voltage of the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer reaches a minimum value;

the first row of data lines are respectively connected with the graphene conductive fiber lines of the first textile structure layer, the first column of data lines are respectively connected with the graphene conductive fiber lines of the third textile structure layer, the first row of data lines and the first column of data lines form a chessboard structure, and the intersection points of the graphene conductive fiber lines of the first textile structure layer and the third textile structure layer are positioned;

Acquiring an intersection point of the first textile structure layer and the third textile structure layer, and switching on the graphene conductive fiber line of the second textile structure layer corresponding to the positioning points to heat or increase the voltage of the graphene conductive fiber line of the second textile structure layer corresponding to the positioning points;

Or the second row of data lines and the second line of data lines form a chessboard structure, intersection points of the graphene conductive fiber lines of the fourth textile structure layer and the fifth textile structure layer are positioned, and the positioned intersection points are sent to a controller;

Acquiring an intersection point of the positioning of the fourth textile structure layer and the positioning of the fifth textile structure layer, and switching on the graphene conductive fiber wires of the corresponding first textile structure layer and/or the second textile structure layer between the positioning points for heating; or the voltage of the graphene conductive fiber line of the corresponding first textile structure layer and/or second textile structure layer between the positioning points is increased;

taking any two graphene conductive fiber lines of the first textile structure layer, the second textile structure layer, the third textile structure layer, the fourth textile structure layer and/or the fifth textile structure layer as humidity acquisition lines, acquiring a third resistance value between the two humidity acquisition lines,

if the third resistance value is larger than the first threshold value, no processing is carried out;

if the third resistance value is within the humidity threshold value, judging whether the humidity acquisition line is the graphene conductive fiber of the first textile structure layer or the second textile structure layer,

If the humidity acquisition line is the graphene conductive fiber of the first textile structure layer or the second textile structure layer, electrifying and heating the humidity acquisition line and the graphene conductive fiber which has the same textile structure layer with the humidity acquisition line and is arranged on two sides of the humidity acquisition line until a third resistance value is larger than a first threshold value;

if the humidity acquisition line is the graphene conductive fiber of the third textile structure layer, the fourth textile structure layer or the fifth textile structure layer, electrifying and heating the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer perpendicular to the humidity acquisition line until the third resistance value is larger than the first threshold value;

and calculating the humidity of the wearing article according to the third resistance value.

according to the heating fabric, the graphene conductive fiber wires of the first textile structure layer and the second textile structure layer are arranged in a mutually crossed mode, and the heat degree of the crossed point is doubled, so that the graphene conductive fiber wires of the first textile structure layer and the second textile structure layer are controlled to be switched on/off, the corresponding areas are controlled to output double heat degrees, and different areas of the heating fabric can output different heat degrees.

According to the heating fabric system, the graphene conductive fiber wires of the first textile structure layer and the second textile structure layer are heated, heartbeat data acquisition, body temperature data acquisition, pressure data acquisition and humidity data acquisition are multiplexed in a time-sharing mode, and multiple functions of heating fabrics are achieved.

according to the method for controlling the heating state of the wearing article based on the physiological data, the human body parameter data are obtained through the heating fabric, and the heating state of the heating fabric is controlled according to the human body parameter feedback data, so that the heating state of the wearing article is most suitable for the human body parameters, and the human body obtains the maximum comfort level.

Drawings

FIG. 1 is a schematic cross-sectional view of a structural layer of a heating fabric of the present invention;

FIG. 2 is a schematic cross-sectional view of a structural layer of the heating fabric of the present invention;

FIG. 3 is a schematic cross-sectional view of a structural layer of the heating fabric of the present invention;

FIG. 4 is a schematic structural view of a first fabric layer and a second fabric layer of a heating fabric of the present invention arranged in a stack;

FIG. 5 is a schematic diagram of the heating of the first and second textile structure layers by all the graphene conductive fibers;

fig. 6 is a schematic diagram of the first textile structure layer and the second textile structure layer of the present invention, in which graphene conductive fibers are heated by wire-bonding.

Detailed Description

The invention is further described with reference to the accompanying drawings.

the following examples are provided to apply the heating fabric of the present invention to shawl and blanket.

example 1

This embodiment heating fabric, heating fabric includes three-layer textile structure, fabric upper portion regional or whole region are the functional area, the first textile structure layer of functional area radially is equipped with many graphite alkene conductive fiber lines, the second textile structure layer latitudinal direction of functional area is equipped with many graphite alkene conductive fiber lines, is equipped with middle textile structure layer between first textile structure layer and the second textile structure layer, middle textile structure layer makes the graphite alkene conductive fiber line on first textile structure layer and the second textile structure layer mutual insulation.

and each or a plurality of graphene conductive fiber wires on the first textile structure layer and the second textile structure layer are controlled to be connected or disconnected with a power supply, so that the heating of the functional area on the fabric can be accurately controlled, the graphene conductive fiber wires of the first textile structure layer and the second textile structure layer are provided with cross points, such as 103 parts drawn by circles in figures 5 and 6, the temperature of the cross points is overlapped, and the heating or double heating of the functional area can be accurately controlled.

example 2

this embodiment heating fabric, on embodiment 1's basis, middle textile structure layer is its third textile structure layer that the latitudinal direction is equipped with many graphite alkene conductive fiber lines, the graphite alkene conductive fiber line of third textile structure layer with the graphite alkene conductive fiber line of second textile structure layer sets up in an insulating way, third textile structure layer with be equipped with first interval structure between the first textile structure layer, first interval structure makes the graphite alkene conductive fiber line of first textile structure layer and the graphite alkene conductive fiber line of third textile structure layer when not having ambient pressure, the clearance sets up, contacts each other when having ambient pressure.

in this embodiment, if the first textile structure layer is a multiplex layer, in this embodiment, when the pressure is applied to the heating fabric, the graphene conductive fiber lines of the first textile structure layer and the third textile structure layer realize a contact positioning function. Under the condition of no pressure, the graphene conductive fiber wires of the first textile structure layer can be heated by switching on a power supply.

in this embodiment, the first spacing structure is a spacing fiber disposed on an opposite surface of the first textile structure layer and/or the third textile structure layer;

or, the first spacing structure is an intermediate elastic textile structure layer arranged between the first textile structure layer and the third textile structure layer, wherein the textile mesh number of the intermediate textile structure layer is 2 to 10 times of the diameter of the conductive fiber;

or, be equipped with a plurality of insulating fiber between the adjacent two conductive fiber of first textile structure layer, third textile structure layer, insulating fiber's extending direction with conductive fiber's extending direction is the same, insulating fiber's diameter be 2 to 10 times conductive fiber diameter, conductive fiber imbeds in the insulating fiber, the insulating fiber of first textile structure layer, third textile structure layer form first interval structure.

example 3

in the heating fabric of this embodiment, on the basis of embodiment 1, the intermediate textile structure layer includes a fourth textile structure layer provided with a plurality of graphene conductive fiber lines in the radial direction, a fifth textile structure layer provided with a plurality of graphene conductive fiber lines in the weft direction, and a second spacing structure disposed between the fourth textile structure layer and the fifth textile structure layer, the graphene conductive fiber wire of the fourth textile structure layer is insulated from the graphene conductive fiber wire of the first textile structure layer, the graphene conductive fiber wire of the fifth textile structure layer and the graphene conductive fiber wire of the second textile structure layer are arranged in an insulating way, the second spacing structure enables the graphene fiber line of the fourth textile structure layer and the graphene conductive fiber line of the fifth textile structure layer to be in clearance arrangement when no external pressure exists, and the graphene fiber line of the fourth textile structure layer and the graphene conductive fiber line of the fifth textile structure layer are in contact with each other when the external pressure exists.

in this embodiment, the second spacer structure is a spacer fiber disposed on a surface of the fourth textile structure layer and/or the fifth textile structure layer opposite to the surface;

Or the second spacing structure is an intermediate elastic textile structure layer arranged between a fourth textile structure layer and a fifth textile structure layer, wherein the textile mesh number of the intermediate textile structure layer is 2-10 times of the diameter of the conductive fiber;

or, be equipped with a plurality of insulating fiber between the adjacent two conductive fiber of fourth textile structure layer, fifth textile structure layer, insulating fiber's extending direction with conductive fiber's extending direction is the same, insulating fiber's diameter be 2 to 10 times conductive fiber diameter, conductive fiber imbeds in the insulating fiber, the insulating fiber of fourth textile structure layer, fifth textile structure layer form the second interval structure.

In the above embodiments, the distance between every two adjacent conductive fibers on the first textile structure layer and the second textile structure layer is equal, and the distance between every two adjacent conductive fibers is 1mm to 10 mm.

in the above embodiments, the distance between two adjacent conductive fibers of the third textile structure layer is 1um to 10 um.

in the above embodiments, the distance between every two adjacent conductive fibers on the fourth textile structure layer and the fifth textile structure layer is equal, and the distance between every two adjacent conductive fibers is 1um to 10 um.

example 4

the heating fabric system of the embodiment comprises the heating fabric, a time-sharing multiplexing switch, a controller, a temperature setting module, a heartbeat collecting module, a body temperature collecting module, a first pressure collecting module, a second pressure collecting module and/or a humidity collecting module, wherein the temperature setting module, the heartbeat collecting module, the body temperature collecting module, the first pressure collecting module, the second pressure collecting module and/or the humidity collecting module are/is wirelessly or wiredly connected with the controller;

If the first resistance value is within the range of the drying resistance threshold value, the voltage between the two heartbeat collecting lines is collected, the drying resistance threshold value is set specifically according to the actual situation, namely, the heating fabric needs to be subjected to preliminary treatment before the voltage is collected, namely, the heating fabric is adjusted to be in a preset state, namely, the voltage value is collected every time under the same condition.

If the voltage value is 0, sending alarm information; if the voltage value is 0, the skin is not attached with the heartbeat collecting line, and at the moment, alarm information is sent out to remind a user.

if the voltage value is within the first voltage threshold range (a, b), outputting the voltage value to a controller; the first voltage threshold range (a, b) is the corresponding measured skin voltage threshold range at 40 to 90 beats/S of human heartbeat.

if the voltage value is smaller than the second voltage threshold value, the controller sends out the starting of heating the first textile structure layer and/or the second textile structure layer until the voltage value is 0 or the voltage value is within the first voltage threshold value range (a, b); the second voltage threshold, i.e. the voltage threshold measured when the textile is wet, is set according to the user's requirements,

if the second resistance value is within the range of the dry resistance threshold value, alarm information is sent out; and when the condition that the skin is not attached with the heartbeat collecting line is indicated, alarm information is sent to remind the user.

If the second resistance value is within the first electric group threshold value range (c, d), outputting the second resistance value to the controller; the corresponding measured skin resistance threshold range is 34-40 ℃ of human body.

example 5

In this embodiment, on the basis of embodiment 1, the controller further includes a time-sharing cycle operating module, where the time-sharing cycle operating module includes: a selection unit and a working time length setting unit, wherein,

the selection unit selects the temperature calculation module, the heartbeat calculation module, the body temperature calculation module and/or the pressure calculation module to perform cycle work;

the working time length setting unit is used for setting the working time length of each module of the temperature setting module, the heartbeat calculating module, the body temperature calculating module and/or the pressure calculating module.

example 6

In the heating fabric system of this embodiment, on the basis of the above embodiment, the controller further includes a physiological heating control module, configured to control a heating state of the graphene conductive fiber wires of the first textile structure layer and/or the second textile structure layer according to data acquired by the heartbeat acquisition module, the body temperature acquisition module, the first pressure acquisition module, the second pressure acquisition module, and/or the humidity acquisition module;

wherein the physiological heating control module comprises: the heating device comprises a heartbeat heating control unit, a body temperature heating control unit, a first pressure heating control unit, a second pressure heating control unit and a humidity heating control unit;

the heartbeat heating control unit compares the acquired voltage value with a standard voltage value range (a1, b1), wherein the standard voltage value range (a1, b1) is a skin voltage threshold range obtained when the normal heartbeat frequency of the human body corresponds to.

the body temperature heating control unit compares the acquired first electric group value with a standard resistance value range (c1, d1), wherein the standard resistance value range (c1, d1) is a skin resistance threshold value range obtained when the normal body temperature frequency of the human body corresponds to.

the first pressure heating control unit is used for acquiring the positioned intersection points of the first textile structure layer and the third textile structure layer, and switching on the graphene conductive fiber lines of the second textile structure layer between the positioning points to heat or increase the voltage of the graphene conductive fiber lines of the second textile structure layer between the positioning points;

the first pressure heating control unit acquires the intersection point of the positioning of the fourth textile structure layer and the positioning of the fifth textile structure layer, and is connected with the graphene conductive fiber wires of the corresponding first textile structure layer and/or the second textile structure layer between the positioning points for heating; or the voltage of the graphene conductive fiber line of the corresponding first textile structure layer and/or second textile structure layer between the positioning points is increased;

the humidity heating control unit judges whether the humidity acquisition line is the graphene conductive fiber of the first textile structure layer or the second textile structure layer,

And if the humidity acquisition line is the graphene conductive fiber of the third textile structure layer, the fourth textile structure layer or the fifth textile structure layer, electrifying and heating the graphene conductive fiber line of the first textile structure layer and/or the second textile structure layer vertical to the humidity acquisition line until the third resistance value is larger than the first threshold value.

example 7

the heating fabric system of the present embodiment is based on the above-described embodiments and, further,

The heartbeat acquisition module: selecting any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer as a first heartbeat acquisition line, successively selecting other graphene conductive fiber lines of the same textile structure layer as second heartbeat acquisition lines respectively, and forming a heartbeat acquisition line group by the first heartbeat acquisition line and the second heartbeat acquisition line; namely, the first heartbeat collecting line and the second heartbeat collecting line are arranged on the same textile structure layer. All the graphene conductive fiber wires except the first heartbeat collecting wire on the first heartbeat collecting wire and the one-layer textile structure layer are paired to collect the skin voltage value, so that the accuracy of collected data can be improved on one hand, and on the other hand, all parts of the textile layer can be traversed, and the textile layer can be adjusted to be in a dry state.

the heartbeat heating control unit acquires a voltage value between two heartbeat acquisition lines of each heartbeat acquisition line group, and calculates the current heartbeat data of the human body according to an average value of the voltage values;

The body temperature acquisition module: selecting any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer as a first body temperature acquisition line, successively selecting other graphene conductive fiber lines of the same textile structure layer as second body temperature acquisition lines respectively, and forming a body temperature acquisition line group by the first body temperature acquisition line and the second body temperature acquisition line; namely, the first body temperature collecting line and the second body temperature collecting line are arranged on the same textile structure layer. All the graphene conductive fiber wires except the first heartbeat collecting wire on the first heartbeat collecting wire and the one-layer textile structure layer are paired to collect the skin resistance value, so that the accuracy of collected data can be improved on one hand, and on the other hand, all parts of the textile layer can be traversed, and the textile layer can be adjusted to be in a dry state.

The body temperature heating control unit acquires a voltage value between two body temperature acquisition lines of each group of body temperature acquisition line groups, and calculates the current body temperature data of the human body according to an average voltage value of the voltage values;

Humidity acquisition module: selecting any one graphene conductive fiber line of a first textile structure layer, a second textile structure layer, a third textile structure layer, a fourth textile structure layer or a fifth textile structure layer as a first body temperature acquisition line; sequentially selecting other graphene conductive fiber wires of the same textile structure layer as second humidity acquisition wires respectively, and forming a humidity acquisition line group by the first humidity acquisition wires and the second humidity acquisition wires; namely, the first humidity acquisition line and the second humidity acquisition line are on the same textile structure layer.

or successively selecting all the graphene conductive fiber wires which are not on the same textile structure layer as second humidity acquisition wires respectively, and forming a humidity acquisition line group by the first humidity acquisition wires and the second humidity acquisition wires; that is, the first humidity acquisition line and the second humidity acquisition line are not on the same textile structure layer, for example, the first humidity acquisition line is on the first textile structure layer, the second humidity acquisition line is on the second textile structure layer, the third humidity acquisition line is on the fourth textile structure layer, and the fifth humidity acquisition line is on the second textile structure layer. So on the one hand can improve the degree of accuracy of the data of gathering, on the other hand can traverse each part of weaving layer, can adjust weaving layer to dry state.

the humidity heating control unit acquires the resistance value between the two humidity acquisition lines of each group of humidity acquisition line groups, and calculates the current humidity data of the fabric according to the average resistance value by taking the average value of the resistance values.

example 8

In the heating fabric system of this embodiment, on the basis of the above embodiments, the controller is a mobile terminal, the heating fabric system further includes a wireless communication module, and the heartbeat acquisition module, the body temperature acquisition module, the first pressure acquisition module, the second pressure acquisition module and/or the humidity acquisition module upload data to the mobile terminal through the wireless communication module;

The wireless communication module comprises a power-saving unit, and the power-saving unit comprises an uploading time setting module and an uploading frequency setting module; the uploading time setting module is used for setting a time period for uploading data by the heartbeat acquisition module, the body temperature acquisition module, the first pressure acquisition module, the second pressure acquisition module and/or the humidity acquisition module, and the uploading time period is divided into a free time period and a busy time period; the uploading frequency setting module is used for setting the uploading frequency in each time period when the heartbeat acquisition module, the body temperature acquisition module, the first pressure acquisition module, the second pressure acquisition module and/or the humidity acquisition module upload data to the mobile terminal, and the uploading frequency setting module sets that the data uploading frequency in a busy time period is greater than that in an idle time period;

the wireless communication module also comprises an uploading frequency changing module which is used for detecting whether the first textile structure layer or the first textile structure layer is heated,

If the textile structure layer is detected to be heated in the idle time period, updating the frequency of the uploaded data to the data uploading frequency in the busy time period;

And if the heating of the textile structure layer is not detected in the busy hour time period, updating the frequency of the uploaded data to the data uploading frequency of the idle time period.

example 9

the embodiment is a method for controlling the heating state of a wearing article based on physiological data, which comprises the following steps:

A garment made using a heated fabric system;

In the normal state of the item of clothing,

if the voltage value is 0, sending alarm information;

calculating the human heartbeat according to the received voltage value;

in this embodiment, any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer is selected as a first heartbeat acquisition line, other graphene conductive fiber lines of the same textile structure layer are sequentially selected as second heartbeat acquisition lines, and the first heartbeat acquisition line and the second heartbeat acquisition line form a heartbeat acquisition line set; namely, the first heartbeat collecting line and the second heartbeat collecting line are arranged on the same textile structure layer. All the graphene conductive fiber wires except the first heartbeat collecting wire on the first heartbeat collecting wire and the one-layer textile structure layer are paired to collect the skin voltage value, so that the accuracy of collected data can be improved on one hand, and on the other hand, all parts of the textile layer can be traversed, and the textile layer can be adjusted to be in a dry state.

acquiring a voltage value between two heartbeat acquisition lines of each heartbeat acquisition line group, taking an average value of the voltage values, and calculating the current heartbeat data of the human body according to the average voltage value;

Selecting any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer as a first body temperature acquisition line, successively selecting other graphene conductive fiber lines of the same textile structure layer as second body temperature acquisition lines respectively, and forming a body temperature acquisition line group by the first body temperature acquisition line and the second body temperature acquisition line; namely, the first body temperature collecting line and the second body temperature collecting line are arranged on the same textile structure layer. All graphite alkene conductive fiber lines except that first body temperature acquisition line on first body temperature acquisition line of this embodiment and the one deck textile structure layer pair and carry out skin resistance value and gather, so can improve the degree of accuracy of the data of gathering on the one hand, and on the other hand can traverse each part of weaving layer, can adjust weaving layer to dry state.

acquiring a voltage value between two body temperature acquisition lines of each group of body temperature acquisition line groups, taking an average value of the voltage values, and calculating current body temperature data of the human body according to the average voltage value;

selecting any one graphene conductive fiber line of a first textile structure layer, a second textile structure layer, a third textile structure layer, a fourth textile structure layer or a fifth textile structure layer as a first body temperature acquisition line; sequentially selecting other graphene conductive fiber wires of the same textile structure layer as second humidity acquisition wires respectively, and forming a humidity acquisition line group by the first humidity acquisition wires and the second humidity acquisition wires; namely, the first humidity acquisition line and the second humidity acquisition line are on the same textile structure layer.

in the following, specific embodiments are described in which the first textile structure layer is used as a pressure sensor in combination with the third textile structure layer or the fourth textile structure layer is used as a pressure sensor in combination with the fifth textile structure layer. In the following embodiments, for convenience of description, the first textile structure layer and the fourth textile structure layer are collectively and equivalently referred to as a first textile layer, the third textile structure layer and the fifth textile structure layer are collectively and equivalently referred to as a second textile layer, and the first spacing structure and the second spacing structure are collectively and equivalently referred to as a spacing structure. The structure of the fabric pressure sensor of the present invention is described in detail below, and the specific embodiments are described as follows:

as shown in fig. 1 to 3, which are schematic cross-sectional views of three different structures of the fabric layer of the present invention, respectively, in fig. 1, the conductive fibers 22 on the fabric layer are arranged at intervals, and the insulating fibers 11 are arranged between adjacent conductive fibers. The diameter of the conductive fibers in fig. 1 is smaller than that of the insulating fibers, so that the insulating fibers are protruded and the conductive fibers are recessed on the surface of the fabric layer after being interwoven into the fabric layer. In fig. 2, the conductive fibers 22 on the fabric layer are arranged at intervals, and the insulating fibers 11 are arranged between adjacent conductive fibers. The diameter of the conductive fibers in fig. 2 is equal to the diameter of the insulating fibers, so that after interweaving into a fabric layer, the insulating fibers and the conductive fibers are in the same plane on the surface of the fabric layer. The diameter of the conductive fibers in fig. 3 is larger than the diameter of the insulating fibers, so that after interweaving into a fabric layer, the conductive fibers are protruded on the surface of the fabric layer and the insulating fibers are recessed. Fig. 4 is a schematic structural diagram of a stacked arrangement of a first fabric layer and a second fabric layer, where an intersection point of the conductive fibers 22a on the first fabric layer and the conductive fibers 22b on the second fabric layer is 12c, and insulating fibers 11a, 11b are respectively disposed between the first conductive fibers and the second conductive fibers.

Example 1

the heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data comprise a first fabric layer and a second fabric layer which are arranged in a stacking mode, wherein a plurality of conducting fibers arranged at intervals are arranged on the first fabric layer and the second fabric layer respectively, so that conducting wire fibers on the same fabric layer are not in mutual contact, the conducting fibers are of linear structures, the conducting fibers are arranged on the fabric layers in a parallel and uniformly-spaced mode, the conducting fibers on the first fabric layer and the conducting fibers on the second fabric layer are arranged in a mutually crossed mode, the conducting fibers on the first fabric layer and the conducting fibers on the second fabric layer are arranged in a crossed mode to form a chessboard structure, ideally, each conducting fiber on the first fabric layer and each conducting fiber on the second fabric layer have a unique intersection point, but in actual situations, the intersection points are difficult to achieve, but most of the conductive fibers on the first fabric layer and the second fabric layer are crossed. A spacing structure is arranged between the first fabric layer and the second fabric layer, in this embodiment, the spacing structure is elastic fibers respectively arranged on the first fabric layer and the second fabric layer, the thickness of the elastic fibers is greater than the diameter of the conductive fibers, that is, the conductive fibers are embedded in the elastic fibers, and the diameters of the conductive fibers on the first fabric layer and the second fabric layer are less than the thicknesses of the first fabric layer and the second fabric layer. The structure is as follows: under the condition that no external force is applied to the first fabric layer and the second fabric layer, the conductive fibers of the first fabric layer and the second fabric layer are spaced apart from each other under the support of the elastic fibers and are not in contact with each other; under the condition that external force is applied to the first fabric layer and the second fabric layer, the conductive fibers of the first fabric layer and the second fabric layer are separated from each other in a gap mode under the support of the elastic fibers and are not in contact with each other, when the external force is applied to the first fabric layer and the second fabric layer, the elastic fibers arranged on the first fabric layer and the second fabric layer are extruded, the conductive fibers stretch out of the elastic fibers, the conductive fibers of the first fabric layer and the second fabric layer are in contact with each other to conduct electricity, the two conductive fibers are intersected at one point, at the moment, coordinate positioning is carried out through a row data line connected with the conductive fibers on the first fabric layer and a row data line connected with the conductive fibers on the second fabric layer, and the pressure value and the position of the compression point can be known.

in this embodiment, the fewer the conductive fibers connected to the same row data line or column data line, that is, the more the row data line and column data line are provided, the higher the positioning accuracy is, but from the manufacturing process and the practical situation, the same row data line or column data line may be connected to more than two conductive fibers.

Example 2

The heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data of the embodiment are the same as the sensor of the fabric structure described in the embodiment 1, and the sensor also comprises a first fabric layer and a second fabric layer which are arranged in a stacked mode, wherein a plurality of conducting fibers arranged at intervals are respectively arranged on the first fabric layer and the second fabric layer. The principle and the manufacturing process of the textile fabric sensor are also substantially the same, and are not described herein again, and the textile fabric sensor described in this embodiment is different from that described in the embodiment in the separation structure provided between the first textile fabric layer and the second textile fabric layer.

the spacing structure in this embodiment is elastic fibers arranged on the first fabric layer, the second fabric layer is not provided with elastic fibers, that is, the diameter of the conductive fibers on the first fabric layer is smaller than the thickness of the first fabric layer, the conductive fibers on the first fabric layer are embedded in the first fabric layer, and the diameter of the conductive fibers on the second fabric layer is the same as the thickness of the second fabric layer. The structure is as follows: under the condition that no external force is applied to the first fabric layer and the second fabric layer, the conductive fibers of the first fabric layer and the second fabric layer are spaced apart from each other under the support of the elastic fibers and are not in contact with each other; when external force is applied to the first fabric layer and the second fabric layer, elastic fibers arranged on the first fabric layer are extruded, at the moment, conductive fibers on the first fabric layer are in contact with and are conductive to wire fibers of the first fabric layer and the second fabric layer, the two conductive fibers are intersected at one point, at the moment, coordinate positioning is carried out through a row data line connected with the conductive fibers on the first fabric layer and a column data line connected with the conductive fibers on the second fabric layer, and the pressure value and the position of a pressed point can be known.

Example 3

The heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data of the embodiment are the same as the sensor of the fabric structure described in the embodiment 2, and the sensor also comprises a first fabric layer and a second fabric layer which are arranged in a stacked mode, wherein a plurality of conducting fibers arranged at intervals are respectively arranged on the first fabric layer and the second fabric layer. The principle and the manufacturing process of the textile fabric sensor are also the same, and are not described herein again, and the textile fabric sensor described in this embodiment is different from that of embodiment 2 in the structure of the second textile fabric.

In this embodiment, the diameter of the conductive fibers on the second fabric layer is larger than that of the second fabric layer, i.e. the conductive wires on the second fabric layer extend out of the second fabric layer, and the thickness of the elastic fibers on the first fabric layer should be not smaller than the sum of the diameters of the conductive fibers on the first fabric layer and the conductive fibers on the second fabric layer.

The structure is as follows: under the condition that no external force is applied to the first fabric layer and the second fabric layer, the conductive fibers of the first fabric layer and the second fabric layer are spaced apart from each other under the support of the elastic fibers and are not in contact with each other; when external force is applied to the first fabric layer and the second fabric layer, elastic fibers on the first fabric layer are extruded, conductive fibers on the second fabric layer stretch into the elastic fibers on the first fabric layer, at the moment, the conductive fibers of the first fabric layer and the second fabric layer are in contact with each other to be conductive, the two conductive fibers are intersected at one point, at the moment, coordinate positioning is carried out through a row data line connected by the conductive fibers on the first fabric layer and a column data line connected by the conductive fibers on the second fabric layer, and the pressure value and the position of a compression point can be known.

example 4

the heating fabric, the heating fabric system and the method for controlling the heating state of the wearing object based on the physiological data comprise a first fabric layer, a second fabric layer and a spacing structure, wherein the first fabric layer and the second fabric layer are arranged in a stacked mode, the spacing structure is arranged between the first fabric layer and the second fabric layer, the first fabric layer and the second fabric layer are both conductive fibers provided with a plurality of linear structures arranged at intervals, and the conductive fibers are arranged on the fabric layers in a parallel and uniformly-spaced arrangement mode. The working principle of the first fabric layer and the second fabric layer is the same as that of the above embodiments, and is not described herein again, and only the difference between this embodiment and the above embodiments is specifically described herein in that the spacing structure is a middle fabric layer disposed between the first fabric layer and the second fabric layer, wherein the weaving mesh number of the middle fabric layer is greater than the diameter of the conductive fiber, that is, the weaving density of the middle fabric layer is lower than that of the first fabric layer and the second fabric layer, and at least one crossing point of the conductive fiber on the first fabric layer and the second fabric layer passes through each weaving gap on the middle fabric layer. In this embodiment, the diameter of the conductive fibers on the first and second fabric layers is the same as the thickness of the first fabric layer.

the structure is as follows: under the condition that no external force is applied to the first fabric layer and the second fabric layer, the conductive fibers of the first fabric layer and the second fabric layer are supported by the middle fabric layer and are arranged away from each other in a clearance mode without contacting; under the condition that external force is applied to the first fabric layer and the second fabric layer, the conductive fibers on the first fabric layer and the second fabric layer are extruded, at the moment, the conductive fibers on the first fabric layer and the second fabric layer penetrate through the weaving gaps of the middle fabric layer to be contacted and conductive, the two conductive fibers are intersected at one point, at the moment, coordinate positioning is carried out through a row data line connected with the conductive fibers on the first fabric layer and a column data line connected with the conductive fibers on the second fabric layer, and the pressure value and the position of a pressed point can be known.

example 5

the heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data of the embodiment comprise a first fabric layer, a second fabric layer and a spacing structure, wherein the first fabric layer and the second fabric layer are arranged in a stacked mode, and the spacing structure is arranged between the first fabric layer and the second fabric layer. The present embodiment is different from embodiment 4 in that the diameter of the conductive fiber on the first fabric layer in this embodiment is equal to that of the first fabric layer, and the thickness of the conductive fiber on the second fabric layer is greater than that of the second fabric layer, that is, the conductive fiber extends out of the second fabric layer. In the structure of this embodiment, there is a certain requirement for the thickness of the middle fabric layer, that is, the thickness of the middle fabric layer is greater than the thickness of the second fabric layer from which the conductive fibers extend.

example 6

the sensor of the fabric structure of this embodiment includes, as in embodiment 5, a first fabric layer, a second fabric layer, and a spacer structure provided between the first fabric layer and the second fabric layer, which are arranged in a stacked manner. The difference from embodiment 5 is that the thickness of the conductive fibers on the first textile layer is greater than that of the first textile layer, i.e., the conductive fibers extend out of the first textile layer. In the structure of this embodiment, there is also a requirement for the thickness of the middle textile layer, i.e., the thickness of the middle textile layer is greater than the sum of the thickness of the conductive fibers of the first textile layer extending out of the first textile layer and the thickness of the conductive fibers of the second textile layer extending out of the second textile layer.

The above embodiments 1 to 6 respectively show the first fabric layer, the second fabric layer, the supporting structure of different structures and the spacing structure of different structures, and no matter what form the spacing structure is arranged, the purpose of the spacing structure is that the conductive fibers on the first fabric layer and the second fabric layer are arranged in a gap without contacting each other under the condition of no external force, no conductive structure is formed between the conductive fibers, and the conductive fibers are contacted with each other under the condition of external force to form a conductive path.

example 7

the heating fabric, the heating fabric system, and the method for controlling the heating state of the wearing article based on the physiological data in this embodiment are different from the above embodiments in the structure of the conductive fibers on the first fabric layer and the second fabric layer, in this embodiment, the conductive fibers on the first fabric layer and the second fabric layer are circular arc lines. The working principle of the conductive fibers on the first and second fabric layers is the same, and the description is omitted here.

example 8

The heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data in the present embodiment are different from the above embodiments in the structure of the conductive fibers on the first fabric layer and the second fabric layer, and in the present embodiment, the conductive fibers on the first fabric layer and the second fabric layer are zigzag lines.

Example 9

The heating fabric, the heating fabric system and the method for controlling the heating state of the wearing article based on the physiological data in the present embodiment are different from the above embodiments in the structures of the conductive fibers on the first fabric layer and the second fabric layer, in the present embodiment, the conductive fibers on the first fabric layer and the second fabric layer are straight lines, and the conductive fibers on the first fabric layer and the second fabric layer intersect but are not perpendicular.

the fabric structure sensor in the above embodiments can accurately position the force application point, but the manufacturing process is relatively complex, and the manufacturing cost is relatively high. The following embodiments describe a textile structure sensor that is less effective in positioning than the above embodiments, but has a relatively simple manufacturing process and low cost.

according to the invention, the functional area of the heating fabric is of a piece of cloth structure, and the graphene conductive fiber wire and other insulating fibers on the fabric cloth are woven together through a textile process.

the above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are also included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope defined by the claims.

Claims

1. A heating fabric system is characterized by comprising a heating fabric, a time-sharing multiplexing switch, a controller, a temperature setting module, a heartbeat acquisition module, a body temperature acquisition module, a pressure acquisition module and a humidity acquisition module, wherein the temperature setting module, the heartbeat acquisition module, the body temperature acquisition module, the pressure acquisition module and the humidity acquisition module are wirelessly or wiredly connected with the controller;

the heating fabric comprises three layers of textile structures, partial areas or all areas on the fabric are functional areas, a first textile structure layer of each functional area is radially provided with a plurality of graphene conductive fiber lines, a second textile structure layer of each functional area is provided with a plurality of graphene conductive fiber lines in a weft direction, an intermediate textile structure layer is arranged between the first textile structure layer and the second textile structure layer, and the graphene conductive fiber lines on the first textile structure layer and the second textile structure layer are mutually insulated by the intermediate textile structure layer;

the middle textile structure layer is a third textile structure layer, a plurality of graphene conductive fiber wires are arranged on the middle textile structure layer in a weft-wise manner, the graphene conductive fiber wires of the third textile structure layer are arranged in an insulated manner with the graphene conductive fiber wires of the second textile structure layer, a first spacing structure is arranged between the third textile structure layer and the first textile structure layer, and the graphene conductive fiber wires of the first textile structure layer and the graphene conductive fiber wires of the third textile structure layer are arranged in a clearance manner when no external pressure exists and are in contact with each other when external pressure exists due to the first spacing structure; or

The middle textile structure layer comprises a fourth textile structure layer, a fifth textile structure layer and a second spacing structure, wherein the fourth textile structure layer is provided with a plurality of graphene conductive fiber wires in the radial direction, the fifth textile structure layer is provided with a plurality of graphene conductive fiber wires in the weft direction, the second spacing structure is arranged between the fourth textile structure layer and the fifth textile structure layer, the graphene conductive fiber wires of the fourth textile structure layer and the graphene conductive fiber wires of the first textile structure layer are arranged in an insulating mode, the graphene conductive fiber wires of the fifth textile structure layer and the graphene conductive fiber wires of the second textile structure layer are arranged in an insulating mode, and the second spacing structure enables the graphene conductive fiber wires of the fourth textile structure layer and the graphene conductive fiber wires of the fifth textile structure layer to be arranged in a clearance mode when external pressure does not exist and to be in contact with each other when the external pressure exists;

if the voltage value is 0, sending alarm information;

if the first resistance value is within the range of the wet resistance, the controller sends out a start-up to heat the first textile structure layer and/or the second textile structure layer until the first resistance value between the two heartbeat acquisition lines is within the range of the dry resistance threshold value;

outputting the second resistance value to the controller if the second resistance value is within the first resistance threshold range (c, d);

if the resistance value is within the moisture resistance threshold value, the controller starts to heat the first textile structure layer and/or the second textile structure layer until the second resistance value between the two body temperature acquisition lines is larger than a first threshold value d or within a first resistance threshold value range (c, d);

The pressure acquisition module is connected with the graphene conductive fiber line of the first textile structure layer through a plurality of first rows of data lines respectively, and is connected with the graphene conductive fiber line of the third textile structure layer through a plurality of first columns of data lines respectively, the first rows of data lines and the first columns of data lines form a chessboard structure, intersection points of the graphene conductive fiber lines of the first textile structure layer and the third textile structure layer are positioned, and the positioned intersection points are sent to the controller; or the pressure acquisition module is respectively connected with the graphene conductive fiber line of the fourth textile structure layer through a plurality of second row data lines and is respectively connected with the graphene conductive fiber line of the fifth textile structure layer through a plurality of second line data lines, the second row data lines and the second line data lines form a chessboard structure, intersection points of the graphene conductive fiber lines of the fourth textile structure layer and the fifth textile structure layer are positioned, and the positioned intersection points are sent to the controller;

the humidity acquisition module is connected with at least one group of humidity acquisition lines of the first textile structure layer, the second textile structure layer and/or the third textile structure layer, each group of humidity acquisition lines consists of any two graphene conductive fiber lines of the first textile structure layer, the second textile structure layer and/or the third textile structure layer, and a third resistance value between the two humidity acquisition lines is acquired, or

the humidity acquisition module is connected with at least one group of humidity acquisition line groups of the first textile structure layer, the second textile structure layer, the fourth textile structure layer and/or the fifth textile structure layer, each group of humidity acquisition line group consists of any two graphene conductive fiber lines of the first textile structure layer, the second textile structure layer, the fourth textile structure layer and/or the fifth textile structure layer, and acquires a third resistance value between the two humidity acquisition lines,

2. the heated fabric system of claim 1, wherein the controller further comprises a time-shared cycle operation module comprising: a selection unit and a working time length setting unit, wherein,

The working time length setting unit is used for setting the working time length of each module of the temperature calculation module, the heartbeat calculation module, the body temperature calculation module and/or the pressure calculation module.

3. the heating fabric system according to claim 1, wherein the controller further comprises a physiological heating control module for controlling a heating state of the graphene conductive fiber wires of the first textile structure layer and/or the second textile structure layer according to data collected by the heartbeat collection module, the body temperature collection module, the pressure collection module and/or the humidity collection module;

wherein the physiological heating control module comprises: the heating device comprises a heartbeat heating control unit, a body temperature heating control unit, a pressure heating control unit and a humidity heating control unit;

the heartbeat heating control unit compares the acquired voltage value with a standard voltage value range (a1, b1),

the body temperature heating control unit compares the acquired second resistance value with a standard resistance value range (c1, d1),

The pressure heating control unit is used for acquiring the positioned intersection points of the first textile structure layer and the third textile structure layer, and switching on the graphene conductive fiber lines of the second textile structure layer between the positioning points to heat or increase the voltage of the graphene conductive fiber lines of the second textile structure layer between the positioning points; or the pressure heating control unit acquires the intersection point of the positioning of the fourth textile structure layer and the fifth textile structure layer, and switches on the graphene conductive fiber wire of the corresponding first textile structure layer and/or second textile structure layer between the positioning points for heating; or the voltage of the graphene conductive fiber line of the corresponding first textile structure layer and/or second textile structure layer between the positioning points is increased;

4. The heated textile system of claim 3,

The heartbeat acquisition module: selecting any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer as a first heartbeat acquisition line, successively selecting other graphene conductive fiber lines of the same textile structure layer as second heartbeat acquisition lines respectively, and forming a heartbeat acquisition line group by the first heartbeat acquisition line and the second heartbeat acquisition line;

the body temperature acquisition module: selecting any one graphene conductive fiber line of a first textile structure layer or a second textile structure layer as a first body temperature acquisition line, successively selecting other graphene conductive fiber lines of the same textile structure layer as second body temperature acquisition lines respectively, and forming a body temperature acquisition line group by the first body temperature acquisition line and the second body temperature acquisition line;

the body temperature heating control unit is used for acquiring the resistance value between the two body temperature acquisition lines of each group of body temperature acquisition line groups, and calculating the current body temperature data of the human body according to the average resistance value by taking the average value of the resistance values;

humidity acquisition module: selecting any one graphene conductive fiber line of the first textile structure layer, the second textile structure layer or the third textile structure layer as a first humidity acquisition line; or selecting any one graphene conductive fiber line of the first textile structure layer, the second textile structure layer, the fourth textile structure layer or the fifth textile structure layer as a first humidity acquisition line;

Sequentially selecting other graphene conductive fiber wires of the same textile structure layer as second humidity acquisition wires respectively, and forming a humidity acquisition line group by the first humidity acquisition wires and the second humidity acquisition wires;

Or successively selecting all the graphene conductive fiber wires which are not on the same textile structure layer as second humidity acquisition wires respectively, and forming a humidity acquisition line group by the first humidity acquisition wires and the second humidity acquisition wires;