CN112263043A - Electromagnetic heating superconductor heat transfer constant temperature warm keeping shoes - Google Patents

Abstract

The invention discloses an electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoe which comprises a superconducting left shunt, a superconducting right shunt, a superconducting heating pipe, a data processing module and a health analysis module, wherein the superconducting left shunt and the superconducting right shunt are installed on one side surface of the outer layer of a shoe body, and the superconducting heating pipe is installed in the middle heat-insulating layer of the shoe body; the server is used for storing shoe body data and personal information of users; the data processing module is used for receiving the shoe body data acquired by the data acquisition module and analyzing the shoe body data; the health analysis module is used for analyzing the health condition of the shoe body user, the temperature and humidity data and the weight data of the superconductor heat transfer constant-temperature heat-preservation shoe are effectively analyzed through the data processing module, the deviation of the temperature, the humidity and the weight is avoided, and the health condition of the heat-preservation shoe user is analyzed through the health analysis module.

Description

Electromagnetic heating superconductor heat transfer constant temperature warm keeping shoes

Technical Field

The invention belongs to the technical field of electromagnetic heating, and relates to superconductor heat transfer constant-temperature warm-keeping shoes, in particular to electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoes.

Background

Electromagnetic heating is also called electromagnetic induction heating, namely an electromagnetic heating technology, and the principle of electromagnetic heating is that an alternating magnetic field is generated through an electronic circuit board component, when a ferrous container is placed on the electromagnetic heating container, the surface of the container cuts alternating magnetic lines of force to generate alternating current on a metal part at the bottom of the container, eddy current enables carriers at the bottom of the container to move randomly at a high speed, and the carriers collide and rub with atoms to generate heat energy. Thereby achieving the effect of heating the article. Since the iron vessel itself generates heat, the heat conversion is particularly high, and up to 95% is a direct heating method. Electromagnetic heating technology is adopted in an electromagnetic oven, an electromagnetic stove and an electromagnetic heating electric cooker.

The existing superconductor heat transfer constant temperature heat preservation shoes on the market have relatively simple structures, and poor heating and heat preservation effects and safety; when the superconductor heat transfer constant-temperature heat-preservation shoe is used, the humidity data, the temperature data and the weight data of the superconductor heat transfer constant-temperature heat-preservation shoe cannot be effectively analyzed, and whether the temperature, the humidity and the weight of the superconductor heat transfer constant-temperature heat-preservation shoe deviate or not cannot be known; the superconductor heat transfer constant-temperature warm-keeping shoes cannot monitor the health condition of users in real time, and therefore the electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoes are provided.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide the electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoes.

The technical problem to be solved by the invention is as follows:

the existing superconductor heat transfer constant temperature heat preservation shoes on the market have relatively simple structures, and poor heating and heat preservation effects and safety; when the superconductor heat transfer constant-temperature heat-preservation shoe is used, the humidity data, the temperature data and the weight data of the superconductor heat transfer constant-temperature heat-preservation shoe cannot be effectively analyzed, and whether the temperature, the humidity and the weight of the superconductor heat transfer constant-temperature heat-preservation shoe deviate or not cannot be known; the superconductor heat transfer constant temperature warm-keeping shoes can not monitor the health condition of users in real time.

The purpose of the invention can be realized by the following technical scheme:

the electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoe comprises a shoe body, wherein a shoe body outer layer is wrapped on the outer side of the shoe body, a shoe body inner layer is wrapped on the inner side of the shoe body, a superconducting left-right shunt is mounted on one side surface of the shoe body outer layer, a shoe body front end reinforcing protective layer is arranged on one side surface of the shoe body outer layer, which is opposite to the superconducting left-right shunt, a shoe body middle heat-insulating layer is arranged in the shoe body, and a superconducting heating pipe is mounted in the shoe body middle heat-insulating layer;

the shoe comprises a shoe body and is characterized in that a controller is assembled in the shoe body, the controller comprises a signal transmitting and receiving module, a data processing module, an alarm module, a health analysis module, a data acquisition module and a timing module, the signal transmitting and receiving module is used for receiving and sending wireless signals, the controller is in communication connection with a mobile terminal through the signal transmitting and receiving module, and the controller is in communication connection with a server through the signal transmitting and receiving module;

the mobile terminal is used for registering and logging after a user inputs personal information and sending the personal information to the server for storage; the server is used for storing shoe body data and personal information of users;

the data acquisition module is used for acquiring shoe body data and sending the acquired shoe body data to the data processing module; the timing module is used for timing the heating time and the using time of the shoe body; the data processing module is used for receiving the shoe body data acquired by the data acquisition module and analyzing the shoe body data;

the health analysis module is used for analyzing the health condition of a person using the shoe body; the alarm module generates an alarm signal when the shoe body is abnormally used and feeds back the alarm signal to the mobile terminal.

Furthermore, the upper side of the shoe body and the side of the reinforcing protective layer at the front end of the shoe body are provided with shoelace holes, one side of the shoe body is provided with a zipper with an opening at the side of the shoe body, one side of the outer layer of the shoe body is connected with a connecting wire, and one end of the connecting wire, which is far away from the shoe body, is provided with a superconducting heating pipe coupling head.

Further, the specific processing procedure of the data processing module is as follows:

s1: acquiring a plurality of temperature values of the shoe body, and marking the temperature values as WDi; acquiring humidity values of a plurality of positions of the shoe body, and marking the humidity values as SDi; acquiring a plurality of weight values of the shoe body, and marking the weight values as ZLi, i is 1, … …, n;

s2: traversing a plurality of temperature values, a plurality of humidity values and a plurality of weight values of the shoe body to obtain a maximum temperature value WDmax, a minimum temperature value WDmin, a maximum humidity value SDmax, a minimum humidity value SDmin, a maximum weight value ZLMax and a minimum weight value ZLmin of the shoe body;

s3: adding the temperature values, the humidity values and the weight values to obtain an average temperature value WDp, an average humidity value SDp and an average weight value ZLp of the shoe body;

s4: setting a temperature threshold WDy, a humidity threshold SDy and a weight threshold ZLy of the shoe body;

s5: calculating a temperature deviation value WPC, a humidity deviation value SPC and a weight deviation value ZPC of the shoe body by using formulas, wherein the specific formulas are as follows:

in the formula, both alpha and beta are fixed values of preset proportionality coefficients;

s6: comparing the temperature deviation value WPC with a temperature threshold WDy, the humidity deviation value SPC with a humidity threshold SDy, and the weight deviation value ZPC with a weight threshold ZLy;

s7: if the WPC is less than or equal to WDy, the temperature of the shoe body is normal, otherwise, the temperature of the shoe body is abnormal;

if the SPC is less than or equal to the SDy, the humidity of the shoe body is normal, otherwise, the humidity of the shoe body is abnormal;

if the ZPC is less than or equal to ZLy, the weight of the shoe body is normal, otherwise, the weight of the shoe body is abnormal.

Further, the specific analysis process of the health analysis module is as follows:

SS 1: acquiring the body temperature TWo of a shoe body user in the previous 15 days, wherein o is 1, … … and 15; four body temperature safety levels were set: the corresponding values of the four body temperature safety levels are Mu, u is 1, 2, 3 and 4, and M1 is more than M2 is more than M3 is more than M4;

SS 11: setting three body temperature safety thresholds TW1, TW2 and TW3, wherein TW1 < TW2 < TW 3;

SS 12: if TWo is less than TW1, the body temperature of the user of the shoe body is judged to be in a no-risk level, and the next step SS16 is carried out;

SS 13: if TW1 is not less than TWo is not less than TW2, the body temperature of the user of the shoe body is judged to be in a low risk level, and the next step SS16 is carried out;

SS 14: if TW2 is more than TWo and less than or equal to TW3, the body temperature of the user of the shoe body is judged to be in the middle risk level, and the next step SS16 is carried out;

SS 15: if TW3 is less than TWo, the body temperature of the user of the shoe body is judged to be in a high risk level, a unqualified health signal is generated, and the process directly enters a step SS 6;

SS 16: acquiring the days d of a medium risk level and the days f of a low risk level in the safety level of the body temperature of the shoe body user in the first 15 days, and calculating by using a formula of Taq (M2 xd + M3 xf + M4) to obtain a safety value Taq of the body temperature of the shoe body user in the first 15 days;

SS 2: acquiring the activity area of a shoe body user 15 days before;

SS 21: four regional risk levels are set: the high risk area, the medium risk area, the low risk area and the risk-free area correspond to values Xe, wherein e is 1, 2, 3 and 4, and X1 is more than X2 and more than X3 and more than X4;

SS 22: if any high-risk area does not exist in the activity area of the shoe body user in the previous 15 days, the next step SS24 is carried out;

SS 23: if any high-risk area exists in the activity area of the shoe body user in the previous 15 days, generating a unqualified health signal, and directly entering the step SS 6;

SS 24: acquiring the number j of the risk areas and the number k of the low risk areas in the activity areas of the shoe body users in the previous 15 days, and calculating a risk value Qfx of the activity areas of the shoe body users in the previous 15 days by using a formula Qfx of X2 xj + X3 xk + X4X;

SS 3: acquiring the shoe wearing time of the user in the previous 15 days, and marking the shoe wearing time of the user as CTo, o is 1, … …, 15;

SS 31: three daily shoe wearing times are set and: the corresponding values of the three shoe wearing time sums are Nv, v is 1, 2 and 3, and N1 is more than N2 and less than N3;

SS 22: acquiring the number of days a reaching the first shoe wearing time sum and the number of days b reaching the second shoe wearing time sum in the previous 15 days of a user, and calculating the shoe wearing time value Csj of the shoe body user in the previous 15 days by using a formula Csj of N1 × a + N2 × b + N3 × to obtain a shoe wearing time value Csj of the shoe body user;

SS 4: obtaining a safety value Taq of the body temperature of a shoe body user, and calculating a health value JK of the shoe body user by using a formula in combination with a risk value Qfx of an activity area and a time value Csj of wearing shoes:

wherein b1, b2 and b3 are fixed values of preset proportionality coefficients, gamma is a fixed value of calculation error compensation, and gamma is 1.65;

SS 5: if the health value exceeds a preset health threshold value, generating a health qualified signal, and if the health value does not exceed the preset health threshold value, generating a health unqualified signal;

SS 6: and the health qualified signal and the health unqualified signal are sent to the mobile terminal through the controller.

Further, the alarm signal is divided into a first-level abnormal signal, a second-level abnormal signal, a third-level abnormal signal and a safety signal, the first-level abnormal signal is notified in a manner of dialing a communication number of an emergency contact and continuously dialing a mobile terminal of a user, the second-level abnormal signal is notified in a manner of dialing a phone call to the mobile terminal of the user within a preset interval time, and the third-level abnormal signal is notified in a manner of sending a message to the mobile terminal of the user through a short message.

Furthermore, the mobile terminal is also provided with an emergency contact person, and the mobile terminal automatically dials the communication number of the emergency contact person when the shoe body is abnormally used.

Furthermore, the data acquisition module comprises a temperature monitoring unit, a humidity monitoring unit and a weight monitoring unit, wherein the temperature monitoring unit is used for monitoring the temperature data of the shoe body, the humidity monitoring unit is used for monitoring the humidity data of the shoe body, the weight monitoring unit is used for monitoring the pressure data of the shoe body, and the temperature monitoring unit is also used for detecting the step temperature of a user; the health analysis module comprises a positioning unit, and the positioning unit is used for positioning and recording the movement track of the shoe body. .

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the superconductor heating pipe and the superconductor pipe are connected with an external power supply through the connecting head of the wiring and the superconductor heating pipe, the superconductor heating pipe and the superconductor pipe are used for heating, the generated heat is transferred to the material part of the inner layer by the middle heat-insulating layer of the shoe body, so that the heating and heat-insulating effects of the shoe body are greatly improved by the arrangement of the middle heat-insulating layer of the shoe body, meanwhile, the shoe body is provided with the superconductivity left and right current dividers which are convenient to divide the current, the side surface of the shoe body is provided with the zipper with the opening at the side surface of the shoe body, the superconductor heat-transfer constant-temperature heat-insulating shoe is convenient to wear, and the front end of the shoe body is reinforced with the protective layer and the;

2. when the superconductor heat transfer constant-temperature heat preservation shoe is used, the data processing module is used for effectively analyzing the humidity data, the temperature data and the weight data of the superconductor heat transfer constant-temperature heat preservation shoe, so that whether the temperature, the humidity and the weight of the superconductor heat transfer constant-temperature heat preservation shoe deviate or not can be known in time;

3. according to the invention, the health analysis module is used for acquiring the body value, the activity area, the wearing time and the like of the user, so that the health condition of the user of the superconductor heat transfer constant-temperature heat-preservation shoe can be analyzed.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the electromagnetic heating superconductor heat transfer constant temperature warm-keeping shoe of the present invention;

FIG. 2 is a side sectional view of the electromagnetic heating superconductor heat transfer constant temperature thermal shoe of the present invention;

fig. 3 is a block diagram of the whole system of the electromagnetic heating superconductor heat transfer constant temperature warm-keeping shoe.

In the figure: 1. a superconducting heating pipe coupling head; 2. a superconducting left and right shunt; 3. the side of the shoe body is provided with a zipper; 4. the shoelace holes; 5. the front end of the shoe body is provided with a reinforced protective layer; 6. an outer layer of the shoe body; 7. the middle heat-insulating layer of the shoe body; 8. a superconducting heating pipe; 9. an inner layer of the shoe body; 10. a connecting wire; 11. a shoe body; 12. and a controller.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, the electromagnetic heating superconductor heat transfer constant temperature warm keeping shoe comprises a superconducting heating pipe coupling head 1, a superconducting left and right shunt 2, a shoe body side opening zipper 3, a shoe lace hole 4, a shoe body front end reinforcing protection layer 5, a shoe body outer layer 6, a shoe body middle heat preservation layer 7, a superconducting heating pipe 8, a shoe body inner layer 9, a connecting wire 10, a shoe body 11 and a controller 12, wherein the shoe body outer layer 6 is wrapped outside the shoe body 11, the shoe body inner layer 9 is wrapped inside the shoe body 11, one side of the shoe body outer layer 6 is connected with the connecting wire 10, one end of the connecting wire 10 far away from the shoe body 11 is provided with the superconducting heating pipe coupling head 1, one side of the shoe body outer layer 6 is provided with the superconducting left and right shunt 2, one side of the shoe body outer layer 6 opposite to the superconducting left and right shunt 2 is provided with the shoe body front end reinforcing protection layer 5, the shoe, a superconducting heating pipe 8 is arranged in the middle heat-insulating layer 7 of the shoe body, a shoelace hole 4 is arranged on one side of the upper side surface of the shoe body 11 and positioned at the front end reinforcing protective layer 5 of the shoe body, and a zipper 3 with an opening on the side surface of the shoe body is arranged on one side surface of the shoe body 11;

the front end reinforcing protective layer 5 of the shoe body is made of thermoplastic polyurethane elastomer rubber material, the outer layer 6 of the shoe body is formed in one step by adopting a composite material forming process, if PVC material is adopted, the middle heat-insulating layer 7 of the shoe body is filled with heat-insulating cotton, and the inner layer 9 of the shoe body is made by mixing materials such as moisture-proof breathable fabric, nano far infrared fiber and pure natural cotton;

a controller 12 is assembled in the shoe body 11, the controller 12 comprises a signal transmitting and receiving module, a data processing module, an alarm module, a power supply module, a health analysis module, a data acquisition module, a timing module and a safety monitoring module, the signal transmitting and receiving module is used for receiving and sending wireless signals, the controller 12 is in communication connection with a mobile terminal through the signal transmitting and receiving module, and the controller 12 is in communication connection with a server through the signal transmitting and receiving module;

the mobile terminal is used for registering and logging after a user inputs personal information, and sending the personal information to the server for storage, wherein the personal information comprises the sex, age, residence address, real-name authentication mobile phone number and the like of the user; the server is used for storing shoe body data and personal information of a user;

the data acquisition module comprises a temperature monitoring unit, a humidity monitoring unit and a weight monitoring unit, wherein the temperature monitoring unit is used for monitoring the temperature data of the shoe body 11, the temperature monitoring unit is specifically a plurality of temperature sensors arranged inside the shoe body 11, the humidity monitoring unit is used for monitoring the humidity data of the shoe body 11, the humidity monitoring unit is specifically a plurality of humidity sensors arranged inside the shoe body 11, the weight monitoring unit is used for monitoring the pressure data of the shoe body 11, the weight monitoring unit is specifically a plurality of weight sensors arranged inside the shoe body 11, and the data acquisition module is used for acquiring the shoe body data and sending the acquired shoe body data to the data processing module; the timing module is used for timing the heating time and the using time of the shoe body 11; the data processing module is used for receiving the shoe body data acquired by the data acquisition module and analyzing the shoe body data, and the specific processing process is as follows:

s1: acquiring a plurality of temperature values of the shoe body 11, and marking the temperature values as WDi; acquiring humidity values of a plurality of positions of the shoe body 11, and marking the humidity values as SDi; acquiring a plurality of weight values of the shoe body 11, and marking the weight values as ZLi, i is 1, … …, n;

s2: traversing a plurality of temperature values, a plurality of humidity values and a plurality of weight values of the shoe body 11 to obtain a maximum temperature value WDmax, a minimum temperature value WDmin, a maximum humidity value SDmax, a minimum humidity value SDmin, a maximum weight value ZLMax and a minimum weight value ZLmin of the shoe body 11;

s3: adding the temperature values, the humidity values and the weight values to obtain an average value, so as to obtain an average temperature value WDp, an average humidity value SDp and an average weight value ZLp of the shoe body 11;

s4: setting a temperature threshold WDy, a humidity threshold SDy and a weight threshold ZLy of the shoe body 11;

s5: the temperature deviation value WPC, the humidity deviation value SPC and the weight deviation value ZPC of the shoe body 11 are calculated by using the following formulas:

in the formula, both alpha and beta are fixed values of preset proportionality coefficients;

s6: comparing the temperature deviation value WPC with a temperature threshold WDy, the humidity deviation value SPC with a humidity threshold SDy, and the weight deviation value ZPC with a weight threshold ZLy;

s7: if the WPC is less than or equal to WDy, the temperature of the shoe body 11 is normal, otherwise, the temperature of the shoe body 11 is abnormal;

if the SPC is less than or equal to SDy, the humidity of the shoe body 11 is normal, otherwise, the humidity of the shoe body 11 is abnormal;

if ZPC is less than or equal to ZLy, the weight of the shoe body 11 is normal, otherwise, the weight of the shoe body 11 is abnormal;

the health analysis module includes the positioning unit, and the positioning unit is used for carrying out the location record to the activity orbit of the shoes body 11, and the temperature monitoring unit still is used for detecting user's step temperature, and the health analysis module is used for carrying out the analysis to 11 user's health condition of the shoes body, and specific analytic process is as follows:

SS 1: acquiring the body temperature TWo, o is 1, … … and 15 of a user of the shoe body 11 in the previous 15 days; four body temperature safety levels were set: the corresponding values of the four body temperature safety levels are Mu, u is 1, 2, 3 and 4, and M1 is more than M2 is more than M3 is more than M4;

SS 11: setting three body temperature safety thresholds TW1, TW2 and TW3, wherein TW1 < TW2 < TW 3;

SS 12: if TWo < TW1, the body temperature of the user of the shoe body 11 is judged to be in a no-risk level, and the next step SS16 is carried out;

SS 13: if TW1 is not less than TWo is not less than TW2, the body temperature of the user of the shoe body 11 is judged to be in a low risk level, and the next step SS16 is carried out;

SS 14: if TW2 is more than TWo and less than or equal to TW3, the body temperature of the user of the shoe body 11 is judged to be in the middle risk level, and the next step SS16 is carried out;

SS 15: if TW3 is less than TWo, the body temperature of the user of the shoe body 11 is judged to be in a high risk level, a health unqualified signal is generated, and the process directly enters a step SS 6;

SS 16: acquiring the days d of the medium risk level and the days f of the low risk level in the safety level of the body temperature of the user of the shoe body 11 in the first 15 days, and calculating the safety value Taq of the body temperature of the user of the shoe body 11 in the first 15 days by using a formula Taq which is M2 xd + M3 xf + M4 × 15-d-f;

SS 2: acquiring the activity area of the shoe body 11 in the 15 days before the user;

SS 21: four regional risk levels are set: the high risk area, the medium risk area, the low risk area and the risk-free area correspond to values Xe, wherein e is 1, 2, 3 and 4, and X1 is more than X2 and more than X3 and more than X4;

SS 22: if any high risk area does not exist in the activity area of the shoe body 11 in the previous 15 days of the user, the next step SS24 is carried out;

SS 23: if any high risk area exists in the activity area of the shoe body 11 in the previous 15 days, generating a unqualified health signal, and directly entering the step SS 6;

SS 24: acquiring the number j of the activity areas in the activity areas of the shoe body 11 user in the previous 15 days and the number k of the low risk areas, and calculating a risk value Qfx of the activity areas of the shoe body 11 user in the previous 15 days by using a formula Qfx of X2 xj + X3 xk + X4 x15-j-k;

SS 3: acquiring the shoe wearing time of the user in the previous 15 days, and marking the shoe wearing time of the user as CTo, o is 1, … …, 15;

SS 31: three daily shoe wearing times are set and: the corresponding values of the three shoe wearing time sums are Nv, v is 1, 2 and 3, and N1 is more than N2 and less than N3;

SS 22: acquiring the number of days a for reaching the first shoe wearing time sum and the number of days b for reaching the second shoe wearing time sum in the previous 15 days of the user, and calculating the shoe wearing time value Csj of the shoe body 11 in the previous 15 days of the user by using a formula Csj of N1 × a + N2 × b + N3 × 15-a-b;

SS 4: obtaining a safety value Taq of the body temperature of a user of the shoe body 11, and calculating a health value JK of the user of the shoe body 11 by using a formula according to a risk value Qfx of an activity area and a shoe wearing time value Csj:

wherein b1, b2 and b3 are fixed values of preset proportionality coefficients, gamma is a fixed value of calculation error compensation, and gamma is 1.65;

SS 5: if the health value exceeds a preset health threshold value, generating a health qualified signal, and if the health value does not exceed the preset health threshold value, generating a health unqualified signal;

SS 6: the health qualified signal and the health unqualified signal are sent to the mobile terminal through the controller 12;

the safety monitoring module carries out safety monitoring to the shoes body 11 when heating, and specific working process is as follows:

p1: obtaining the temperature W1 of the shoe body 11 at the current time T1, obtaining the temperature W2 of the shoe body 11 after a period of time T2, and obtaining the temperature Wn of the shoe body 11 again after a period of time Tn;

p2: calculating the heating rate S1 of the shoe body 11 in the time period T1 to T2 and the heating rate Sn-1 of the shoe body 11 in the time period Tn-1 to Tn by using the formula S1, namely W2-W1/T2-T1 … … Sn-1, namely Wn-Wn-1/Tn-Tn-1, and so on to obtain the heating rates of the shoe body 11 in a plurality of time periods;

p3: adding the heating rates of the shoe bodies 11 in a plurality of time periods to obtain an average heating rate SP of the shoe bodies 11;

p4: a user inputs the heating temperature of the shoe body 11 through the mobile terminal, and marks the heating temperature as WJ;

p5: calculating the required time length T of the shoe body 11 reaching the use temperature by using a formula T ═ WJ/SP, timing the actual time length of the shoe body 11 reaching the required use temperature by using a timing module, and marking the actual time length as TS;

p6: presetting a heating time difference threshold Ty, and comparing the actual time length TS with the required time length T;

p61: when TS is equal to T, the shoe body 11 is heated normally, and a heating normal signal is generated and fed back to the controller 12;

p62: when TS ≠ T2, the actual time difference Tc is obtained using the formula Tc ═ TS-T | or Tc ═ T-TS |;

p63: when Tc is less than or equal to Ty, the shoe body 11 is heated normally, and a safety signal is generated and fed back to the controller 12;

p64: when Tc is more than Ty, the shoe body 11 is abnormally heated, and a three-level abnormal signal is generated and fed back to the controller 12;

p7: setting the upper limit value of the temperature of the shoe body 11, and marking the upper limit value of the temperature as Wmax; obtaining the temperature WG of the superconducting heating pipe 8 and the temperature WN of the inner layer 9 of the shoe body, and subtracting the temperature WN of the cap body lining from the temperature WG of the superconducting heating pipe 8 to obtain a temperature loss value WH;

p8: setting a temperature loss threshold value Wy, when WH is less than or equal to Wy, heating the shoe body 11 normally, generating a safety signal and feeding the signal back to the controller 12;

p9: when WH is larger than Wy, the shoe body 11 is heated abnormally, and a secondary abnormal signal is generated and fed back to the controller 12;

when WG is larger than Wmax, the shoe body 11 is heated abnormally, and a first-level abnormal signal is generated and fed back to the controller 12;

p10: the generated alarm signal is fed back to the controller 12, and the controller 12 generates a control signal to be loaded to the alarm module;

the alarm module generates an alarm signal when the shoe body 11 is abnormally used and feeds back the alarm signal to the mobile terminal, wherein the alarm signal is divided into a first-level abnormal signal, a second-level abnormal signal, a third-level abnormal signal and a safety signal, the first-level abnormal signal is notified in a mode of dialing a communication number of an emergency contact and continuously dialing the mobile terminal of a user, the second-level abnormal signal is notified in a mode of dialing a telephone to the mobile terminal of the user within a preset interval time, and the third-level abnormal signal is notified in a mode of sending a message to the mobile terminal of the user through a short message, a WeChat, a QQ and the like; the power supply module is used for supplying power to the electric equipment of the shoe body 11;

the mobile terminal is also provided with an emergency contact person, and the mobile terminal automatically dials the communication number of the emergency contact person when the shoe body 11 is abnormal in use.

When the electromagnetic heating superconductor heat transfer constant temperature warm keeping shoe works, the superconductor heating pipe and the superconductor pipe 3 are connected with an external power supply through a connecting wire and a superconductor heating pipe connecting head 1, the superconductor heating pipe and the superconductor pipe 3 are heated, and the generated heat is transferred to the material part of an internal layer through a shoe body middle heat preservation layer 7, so that the heating and warm keeping can be carried out by the feet of a user, the heating and heat preservation effect of the shoe body 11 is greatly improved due to the arrangement of the shoe body middle heat preservation layer 7, meanwhile, a superconductor left and right shunt 2 is arranged on the shoe body 11 and is convenient to shunt, a shoe body side opening zipper 3 is arranged on the side surface of the shoe body 11, the superconductor heat transfer constant temperature warm keeping shoe is convenient to wear, a protective layer 5 and a shoe body outer layer 6 are enhanced at the front end of the shoe body 11, the attractiveness of;

analyzing the shoe body data through a data processing module, firstly obtaining a plurality of temperature values WDi, a plurality of humidity values SDi and a plurality of weight values ZLi of the shoe body 11, traversing the plurality of temperature values, the plurality of humidity values and the plurality of weight values of the shoe body 11 to obtain a maximum temperature value WDmax, a minimum temperature value WDmin, a maximum humidity value SDmax, a minimum humidity value SDmin, a maximum weight value ZLMax and a minimum weight value ZLmin of the shoe body 11, adding the plurality of temperature values, the plurality of humidity values and the plurality of weight values to obtain an average temperature value WDp, an average humidity value SDp and an average weight value ZLp of the shoe body 11, setting a temperature threshold value WDy, a humidity threshold value SDy and a weight threshold value ZLy of the shoe body 11, and utilizing a formula

Calculating the temperature deviation value WPC, humidity deviation value SPC and weight deviation value ZPC of the shoe body 11, and calculating the temperature deviation value WPC, the temperature threshold value WDy and the humidity deviation valueComparing the SPC with a humidity threshold value SDy and a weight deviation value ZPC with a weight threshold value ZLy, if WPC is less than or equal to WDy, the temperature of the shoe body 11 is normal, otherwise, the temperature of the shoe body 11 is abnormal, if SPC is less than or equal to SDy, the humidity of the shoe body 11 is normal, otherwise, the humidity of the shoe body 11 is abnormal, if ZPC is less than or equal to ZLy, the weight of the shoe body 11 is normal, otherwise, the weight of the shoe body 11 is abnormal;

the health condition of the shoe body 11 user is analyzed through the health analysis module, the body temperature TWo of the shoe body 11 user in the previous 15 days is firstly obtained, and four body temperature safety levels are set: setting three body temperature safety thresholds TW1, TW2 and TW3, when TWo < TW1, judging that the body temperature of a user of the shoe body 11 is in a no-risk level, when TW1 is not more than TWo and not more than TW2, judging that the body temperature of the user of the shoe body 11 is in a low-risk level, when TW2 < TWo is not more than TW3, judging that the body temperature of the user of the shoe body 11 is in a medium-risk level, acquiring the days d of the medium-risk level and the days f of the low-risk level in the body temperature safety levels of the user of the shoe body 11 in the previous 15 days, calculating a safety value Taq of the body temperature of the user of the shoe body 11 in the previous 15 days by using a formula of M2 x d + M3 x f + M4 x 15-d-f, then acquiring an activity area of the user of the shoe body 11 in the previous 15 days, and setting four area risk levels: when any high risk area does not exist in the activity areas of the shoe body 11 in the previous 15 days, acquiring the number j of the medium risk areas and the number k of the low risk areas in the activity areas of the shoe body 11 in the previous 15 days, calculating a risk value Qfx of the activity areas of the shoe body 11 in the previous 15 days by using a formula Qfx (X2 xj + X3 xk + X4 x15-j-k), acquiring the shoe wearing time CTo of the user in the previous 15 days, and setting three shoe wearing time per day sums: the first shoe wearing time sum, the second shoe wearing time sum and the third shoe wearing time sum are obtained, the days a reaching the first shoe wearing time sum and the days b reaching the second shoe wearing time sum in the previous 15 days of a user are obtained, the time value Csj of the shoe body 11 in the previous 15 days of the user is calculated by using a formula Csj which is N1 × a + N2 × b + N3 × 15-a-b, the safety value Taq of the body temperature of the user of the shoe body 11 is combined with the risk value Qfx of the activity area and the time value Csj of the shoe wearing is combined by using the formula

Calculating to obtain a health value JK of a user of the shoe body 11, if the health value exceeds a preset health threshold value, generating a qualified health signal, if the health value does not exceed the preset health threshold value, generating an unqualified health signal, meanwhile, when any high-risk area exists in an activity area 15 days before the user of the shoe body 11, generating a unqualified health signal, and when TW3 is less than TWo, judging that the body temperature of the user of the shoe body 11 is at a high risk level, generating a unqualified health signal, and transmitting the qualified health signal and the unqualified health signal to a mobile terminal through a controller 12;

the method comprises the steps of carrying out safety monitoring on a shoe body 11 during heating through a safety monitoring module, obtaining the temperature W1 of the shoe body 11 at the current time T1, obtaining the temperature W2 of the shoe body 11 after a period of time T2, obtaining the temperature Wn of the shoe body 11 again after a period of time Tn, calculating the heating rate S1 of the shoe body 11 in a time period T1 to T2 and the heating rate Sn-1 of the shoe body 11 in a time period Tn-1 to Tn by using a formula S1-W2-W1/T2-T1 … … Sn-1-Wn-1/Tn-Tn-1, and so on to obtain the heating rates of the shoe body 11 in a plurality of time periods, adding the heating rates of the shoe body 11 in the plurality of time periods to obtain an average heating rate SP of the shoe body 11, inputting the heating temperature WJ of the shoe body 11 through a mobile terminal by a user, calculating the time length T needed for the shoe body 11 to reach the use temperature T by using a formula T/SP, timing an actual time length TS of the shoe body 11 reaching a required use temperature by using a timing module, presetting a heating time difference threshold Ty, comparing the actual time length TS with a required time length T, when the TS is equal to T, the shoe body 11 is heated normally, generating a heating normal signal and feeding back the signal to the controller 12, when the TS is not equal to T2, obtaining an actual time difference Tc by using a formula Tc of | TS-T | or Tc of | T-TS | and if the Tc is less than or equal to Ty, heating the shoe body 11 normally, generating a safety signal and feeding back the safety signal to the controller 12, when the Tc is greater than Ty, generating a three-level abnormal signal and feeding back the signal to the controller 12, and simultaneously, setting an upper temperature limit value Wmax of the shoe body 11; obtaining the temperature WG of the superconducting heating pipe 8 and the temperature WN of the inner layer 9 of the shoe body, subtracting the temperature WN of the cap body lining from the temperature WG of the superconducting heating pipe 8 to obtain a temperature loss value WH, setting a temperature loss threshold Wy, when the WH is less than or equal to Wy, the shoe body 11 is normally heated, generating a safety signal and feeding the safety signal back to the controller 12, when the WH is greater than Wy, the shoe body 11 is abnormally heated, generating a second-level abnormal signal and feeding the second-level abnormal signal back to the controller 12, when the WG is greater than Wmax, the shoe body 11 is abnormally heated, generating a first-level abnormal signal and feeding the first-level abnormal signal back to the controller 12, finally generating an alarm signal and feeding the alarm signal to the alarm.

The above formulas are all calculated by taking the numerical value of the dimension, the formula is a formula which obtains the latest real situation by acquiring a large amount of data and performing software simulation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (7)

1. The electromagnetic heating superconductor heat transfer constant-temperature warm-keeping shoe comprises a shoe body (11) and is characterized in that the outer side of the shoe body (11) is wrapped with a shoe body outer layer (6), the inner side of the shoe body (11) is wrapped with a shoe body inner layer (9), a superconducting left-right shunt (2) is installed on one side face of the shoe body outer layer (6), a shoe body front end reinforcing protective layer (5) is arranged on the shoe body outer layer (6) and on the side face opposite to the superconducting left-right shunt (2), a shoe body middle heat insulation layer (7) is arranged inside the shoe body (11), and a superconducting heating pipe (8) is installed inside the shoe body middle heat insulation layer (7);

the shoe comprises a shoe body (11), and is characterized in that a controller (12) is assembled in the shoe body (11), the controller (12) comprises a signal transmitting and receiving module, a data processing module, an alarm module, a health analysis module, a data acquisition module and a timing module, the signal transmitting and receiving module is used for receiving and sending wireless signals, the controller (12) is in communication connection with a mobile terminal through the signal transmitting and receiving module, and the controller (12) is in communication connection with a server through the signal transmitting and receiving module;

the mobile terminal is used for registering and logging after a user inputs personal information and sending the personal information to the server for storage; the server is used for storing shoe body data and personal information of users;

the data acquisition module is used for acquiring shoe body data and sending the acquired shoe body data to the data processing module; the timing module is used for timing the heating time and the using time of the shoe body (11); the data processing module is used for receiving the shoe body data acquired by the data acquisition module and analyzing the shoe body data;

the health analysis module is used for analyzing the health condition of a user of the shoe body (11); the alarm module generates an alarm signal when the shoe body (11) is abnormally used and feeds back the alarm signal to the mobile terminal.

2. The electromagnetic heating superconductor heat transfer constant temperature warm keeping shoe of claim 1, characterized in that shoelace holes (4) are opened on one side of the shoe body (11) and on one side of the shoe body front end reinforcing protective layer (5), a zipper (3) with an opening on the shoe body side is installed on one side of the shoe body (11), a connecting wire (10) is connected on one side of the shoe body outer layer (6), and a superconducting heating pipe coupling head (1) is installed on one end of the connecting wire (10) far away from the shoe body (11).

3. The electromagnetic heating superconductor heat transfer constant temperature warm-keeping shoe as claimed in claim 1, wherein the data processing module comprises the following specific processing procedures:

s1: acquiring a plurality of temperature values of the shoe body (11), and marking the temperature values as WDi; acquiring humidity values of a plurality of positions of the shoe body (11), and marking the humidity values as SDi; acquiring a plurality of weight values of the shoe body (11), and marking the weight values as ZLi, i is 1, … …, n;

s2: traversing a plurality of temperature values, a plurality of humidity values and a plurality of weight values of the shoe body (11) to obtain a maximum temperature value WDmax, a minimum temperature value WDmin, a maximum humidity value SDmax, a minimum humidity value SDmin, a maximum weight value ZLMax and a minimum weight value ZLmin of the shoe body (11);

s3: adding the temperature values, the humidity values and the weight values to obtain an average temperature value WDp, an average humidity value SDp and an average weight value ZLp of the shoe body (11);

s4: setting a temperature threshold WDy, a humidity threshold SDy and a weight threshold ZLy of the shoe body (11);

s5: the temperature deviation value WPC, the humidity deviation value SPC and the weight deviation value ZPC of the shoe body (11) are calculated by using the following formulas:

in the formula, both alpha and beta are fixed values of preset proportionality coefficients;

s6: comparing the temperature deviation value WPC with a temperature threshold WDy, the humidity deviation value SPC with a humidity threshold SDy, and the weight deviation value ZPC with a weight threshold ZLy;

s7: if the WPC is less than or equal to WDy, the temperature of the shoe body (11) is normal, otherwise, the temperature of the shoe body (11) is abnormal;

if the SPC is less than or equal to SDy, the humidity of the shoe body (11) is normal, otherwise, the humidity of the shoe body (11) is abnormal;

if ZPC is less than or equal to ZLy, the weight of the shoe body (11) is normal, otherwise, the weight of the shoe body (11) is abnormal.

4. The electromagnetic heating superconductor heat transfer constant temperature warm-keeping shoe as claimed in claim 1, wherein the health analysis module comprises the following specific analysis processes:

SS 1: acquiring the body temperature TWo, o is 1, … … and 15 of a user of the shoe body (11) in the previous 15 days; four body temperature safety levels were set: the corresponding values of the four body temperature safety levels are Mu, u is 1, 2, 3 and 4, and M1 is more than M2 is more than M3 is more than M4;

SS 11: setting three body temperature safety thresholds TW1, TW2 and TW3, wherein TW1 < TW2 < TW 3;

SS 12: if TWo is less than TW1, the body temperature of the user of the shoe body (11) is judged to be in a non-dangerous level, and the next step SS16 is carried out;

SS 13: if TW1 is not less than TWo is not less than TW2, the body temperature of the user of the shoe body (11) is judged to be in a low risk level, and the next step SS16 is carried out;

SS 14: if TW2 is more than TWo and less than or equal to TW3, the body temperature of the user of the shoe body (11) is judged to be in the middle risk level, and the next step SS16 is carried out;

SS 15: if TW3 is less than TWo, the body temperature of the user of the shoe body (11) is judged to be in a high risk level, a health unqualified signal is generated, and the process directly enters a step SS 6;

SS 16: acquiring days d of a medium risk level and days f of a low risk level in the safety level of the body temperature of the user of the shoe body (11) in the first 15 days, and calculating the safety value Taq of the body temperature of the user of the shoe body (11) in the first 15 days by using a formula Taq (M2 xd + M3 xf + M4 × (15-d-f);

SS 2: acquiring the activity area of the shoe body (11) in 15 days before the user;

SS 21: four regional risk levels are set: the high risk area, the medium risk area, the low risk area and the risk-free area correspond to values Xe, wherein e is 1, 2, 3 and 4, and X1 is more than X2 and more than X3 and more than X4;

SS 22: if any high-risk area does not exist in the activity area of the shoe body (11) in the previous 15 days of the user, the next step SS24 is carried out;

SS 23: if any high-risk area exists in the activity area of the shoe body (11) in the previous 15 days of the user, generating a health unqualified signal, and directly entering the step SS 6;

SS 24: acquiring the number j of the activity areas in the 15 days before the use of the shoe body (11) and the number k of the low risk areas, and calculating a risk value Qfx of the activity areas in the 15 days before the use of the shoe body (11) by using a formula Qfx of X2 xj + X3 xk + X4X (15-j-k);

SS 3: acquiring the shoe wearing time of the user in the previous 15 days, and marking the shoe wearing time of the user as CTo, o is 1, … …, 15;

SS 31: three daily shoe wearing times are set and: the corresponding values of the three shoe wearing time sums are Nv, v is 1, 2 and 3, and N1 is more than N2 and less than N3;

SS 22: acquiring the days a and b reaching the first shoe wearing time sum and the second shoe wearing time sum in the previous 15 days of the user, and calculating the shoe wearing time value Csj of the shoe body (11) in the previous 15 days of the user by using a formula Csj of N1 × a + N2 × b + N3 × (15-a-b);

SS 4: obtaining a safety value Taq of the body temperature of a user of the shoe body (11), and calculating a health value JK of the user of the shoe body (11) by using a formula according to a risk value Qfx of an activity area and a shoe wearing time value Csj:

wherein b1, b2 and b3 are fixed values of preset proportionality coefficients, gamma is a fixed value of calculation error compensation, and gamma is 1.65;

SS 5: if the health value exceeds a preset health threshold value, generating a health qualified signal, and if the health value does not exceed the preset health threshold value, generating a health unqualified signal;

SS 6: the health-qualified signal and the health-unqualified signal are sent to the mobile terminal through the controller (12).

5. The electromagnetic heating superconductor heat transfer constant temperature thermal shoe as claimed in claim 1, wherein the alarm signal is divided into a primary abnormal signal, a secondary abnormal signal, a tertiary abnormal signal and a safety signal, the primary abnormal signal is notified by dialing a communication number of an emergency contact and continuously dialing a mobile terminal of a user, the secondary abnormal signal is notified by dialing a phone call to the mobile terminal of the user within a preset interval time, and the tertiary abnormal signal is notified by sending a message to the mobile terminal of the user through a short message.

6. The electromagnetic heating superconductor heat transfer constant temperature warm-keeping shoe as claimed in claim 1, characterized in that the mobile terminal is further provided with an emergency contact, and the mobile terminal automatically dials the communication number of the emergency contact when the shoe body (11) is abnormally used.

7. The electromagnetic heating superconductor heat transfer constant temperature warm shoe as claimed in claim 1, wherein the data acquisition module comprises a temperature monitoring unit, a humidity monitoring unit and a weight monitoring unit, the temperature monitoring unit is used for monitoring the temperature data of the shoe body (11), the humidity monitoring unit is used for monitoring the humidity data of the shoe body (11), the weight monitoring unit is used for monitoring the pressure data of the shoe body (11), and the temperature monitoring unit is also used for detecting the step temperature of a user; the health analysis module comprises a positioning unit, and the positioning unit is used for positioning and recording the movement track of the shoe body (11).

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