CN115551125A - Heating control method and system for heating clothes and heating clothes - Google Patents

Abstract

The invention discloses a heating control method and a heating control system for a heating garment and the heating garment, wherein the heating control method for the heating garment is suitable for a heating system with N heating zones; setting a final target temperature value; dividing the N heating zones into M heating groups; obtaining a time-sharing target temperature value according to a first preset rule; sequentially carrying out circulating time-sharing heating on the M heating groups; if the temperature of the N heating areas does not reach the time-sharing target temperature value, the circulation time-sharing heating is continued; if the temperatures of the N heating areas reach the time-sharing target temperature value but do not reach the final target temperature value, increasing the time-sharing target temperature value according to a second preset rule, and continuing to circularly heat in a time-sharing manner; and after the final target temperature value is reached, keeping the constant temperature of the N heating zones. The invention adopts zone heating and groups the heating zones, thereby saving the power supply pressure of the power supply, improving the comfort level of a user and keeping constant temperature after reaching the preset target temperature.

Description

Heating control method and system for heating clothes and heating clothes

Technical Field

The invention relates to the technical field of garment heating, in particular to a heating control method and system for a heating garment and the heating garment.

Background

The heating clothes at present are generally heated by heating the whole heating wire arranged on the heating clothes, and the heating wire is usually in a piece. In terms of hardware, heating clothes with different sizes need to customize heating sheets or heating wires with different specifications, so that the manufacturing cost is high. In the aspect of heating effect and heat preservation effect, the elasticity degree of each position of heating clothes itself has the difference, and the human body also can make each position of heating clothes produce the folding of different degrees when moving, and other various factors in addition, the speed of the heat loss of each position of heating clothes is inconsistent, because present heating clothes is whole heating again, leads to in-process in the use, can appear heating clothes each position temperature inhomogeneous, and some positions overcooling or overheated condition, and the user can't obtain good experience.

Disclosure of Invention

The invention aims to provide a heating control method and system for a heating garment and the heating garment.

The technical scheme adopted by the invention for solving the technical problems is as follows: a heating control method for a heating garment is constructed, the heating control method is suitable for a heating system with N heating zones, N is more than or equal to 2, and the heating control method comprises the following steps:

s1, setting final target temperature values of the N heating zones;

s2, dividing the N heating zones into M heating groups, wherein M is more than or equal to 2 and less than or equal to N;

s3, obtaining a time-sharing target temperature value according to a first preset rule;

s4, sequentially carrying out circulating time-sharing heating on the M heating groups;

s5, judging whether the first real-time temperatures of the N heating zones are larger than or equal to the time-sharing target temperature value or not, and if so, executing a step S6; if not, executing the step S4;

s6, judging whether the first real-time temperature is greater than or equal to the final target temperature value, if so, executing a step S7; if not, increasing the time-sharing target temperature value according to a second preset rule, and returning to execute the step S4;

and S7, keeping the N heating zones at the final target temperature value continuously.

Preferably, in the heating control method for a heating garment provided by the present invention, step S3 includes:

and acquiring second real-time temperature values of the N heating zones, calculating the temperature average value of the N heating zones according to the second real-time temperature values, and adding a first preset value to the temperature average value to obtain a time-sharing target temperature value.

Preferably, in the heating control method for heating clothes provided by the present invention, step S4 includes: and preferentially heating the heating group comprising the heating zone with the lowest second real-time temperature value.

Preferably, in the heating control method for heating clothes provided by the present invention, in step S4, each of the heating groups shares a time slice.

Preferably, in the heating control method for heating clothes provided by the present invention, step S4 includes:

s401, let i =1, j =1;

s402, heating the jth heating group in the ith time slice;

s403, judging whether j is equal to M, if yes, executing a step S5; if not, let i = i +1, j = j +1, and return to execute step S402.

Preferably, in the heating control method for heating clothes provided by the present invention, step S4 includes: and if the heating zones in each heating group reach the time-sharing target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

Preferably, in the heating control method for a heating garment according to the present invention, in step S6, if no, increasing the time-sharing target temperature value according to a second preset rule, and returning to execute step S4 includes:

and adding a second preset value to the time-sharing target temperature value, and returning to execute the step S4.

Preferably, in the heating control method for heating clothes provided by the present invention, step S7 includes:

s701, sequentially carrying out circulating time-sharing heating on the M heating groups;

s702, judging whether the third real-time temperature of the N heating zones is greater than or equal to the final target temperature value or not, if so, executing a step S703; if not, executing step S701;

and S703, after the preset time interval, returning to execute the step S702.

The invention also constructs a heating control system for the heating suit, the heating suit is provided with N heating zones, N is more than or equal to 2, and the heating control system comprises:

the final target temperature value setting module is used for setting final target temperature values of the N heating zones;

the grouping module is used for dividing the N heating zones into M heating groups, wherein M is more than or equal to 2 and less than or equal to N;

the time-sharing target temperature value setting module is used for obtaining a time-sharing target temperature value according to a first preset rule;

the heating module is used for sequentially carrying out circulating time-sharing heating on the M heating groups;

the first judging module is used for judging whether the first real-time temperature of the N heating areas reaches the time-sharing target temperature value or not, and if so, the second judging module is executed; if not, executing a heating module;

the second judgment module is used for judging whether the first real-time temperature reaches the final target temperature value or not, and if so, the constant temperature module is executed; if not, executing the improving module, and returning to execute the heating module;

the increasing module is used for increasing the time-sharing target temperature value according to a second preset rule;

and the constant temperature module is used for enabling the N heating zones to be continuously kept at the final target temperature value.

The invention also constructs a heating suit which comprises a heating suit body, heating zones arranged on all parts of the heating suit body and the heating control system for the heating suit.

By implementing the invention, the following beneficial effects are achieved:

the invention provides a heating control method and system for a heating garment and the heating garment, wherein the heating control method for the heating garment is suitable for a heating system with N heating zones; setting a final target temperature value; dividing the N heating zones into M heating groups; obtaining a time-sharing target temperature value according to a first preset rule; sequentially carrying out circulating time-sharing heating on the M heating groups; if the temperature of the N heating areas does not reach the time-sharing target temperature value, the circulation time-sharing heating is continued; if the temperatures of the N heating areas reach the time-sharing target temperature value but do not reach the final target temperature value, increasing the time-sharing target temperature value according to a second preset rule, and continuing to circularly heat in a time-sharing manner; and after the final target temperature value is reached, keeping the constant temperature of the N heating zones. The invention adopts zone heating and groups the heating zones, thereby saving the power supply pressure of the power supply, improving the comfort level of a user and keeping constant temperature after reaching the preset target temperature.

According to the invention, the time-sharing target temperature value is obtained according to the first preset rule, the temperature difference between the heating zones is reduced as much as possible, and the condition that a user using the heating suit cannot feel cold and the like caused by overlarge temperature difference between the heating zones is ensured. According to the invention, the time-sharing target temperature value is increased according to the second preset rule, and then the heating zones are subjected to grouped cyclic time-sharing heating, so that the heating clothes are stably heated in the heating process, the user feeling is mild, the power supply load is small, and the effect is good.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a flow chart of one embodiment of a heating control method for a heating garment of the present invention;

FIG. 2 is a schematic structural view of an embodiment of the heating garment of the present invention;

FIG. 3 is a schematic circuit diagram of an embodiment of the heating garment of the present invention.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

It should be noted that the flow charts shown in the drawings are only exemplary and do not necessarily include all the contents and operations/steps, nor do they necessarily have to be executed in the order described. For example, some operations/steps may be decomposed, and some operations/steps may be combined or partially combined, so that the actual execution sequence may be changed according to the actual situation.

The block diagrams shown in the figures are functional entities only and do not necessarily correspond to physically separate entities. I.e. these functional entities may be implemented in the form of software, or in one or more hardware modules or integrated circuits, or in different networks and/or processor means and/or microcontroller means.

Referring to fig. 1, a first embodiment of the disclosure of the present invention discloses a heating control method for a heating garment, which is suitable for a heating system having N heating zones, where N is equal to or greater than 2, and includes the following steps:

s1, setting final target temperature values of the N heating zones.

S2, dividing the N heating areas into M heating groups, wherein M is more than or equal to 2 and less than or equal to N. For example, there may be 8 heating zones, which may be divided into 2, 3, 4, 5, 6, 7 or 8 groups, and each group may or may not include the same number of heating zones. Preferably, the number of heating zones included in each heating group should be kept as close as possible to avoid the situation that the power supply load of the power supply has great difference in each time slice and is liable to damage the service life of the power supply.

And S3, obtaining a time-sharing target temperature value according to a first preset rule. The time-sharing target temperature value is a staged target temperature value of all heating zones in the cyclic time-sharing heating process.

And S4, sequentially carrying out circulating time-sharing heating on the M heating groups. The cyclic time-sharing heating means that each heating group exclusively occupies one time slice to heat, and when the step returns to the step S4 after all the heating groups are heated for the first time and other steps are performed, all the M heating groups are heated in time slices from the first heating group. Since M heating groups are heated repeatedly one round by one round, and each heating group is separated to monopolize one time slice, the process is called cyclic time-sharing heating.

S5, judging whether the first real-time temperatures of the N heating zones are larger than or equal to the time-sharing target temperature value, if so, indicating that the N heating zones finish the heating task of the stage, and executing the step S6; if not, representing that part of the heating areas still need to be heated to reach the time-sharing target temperature value of the stage, executing step S4.

S6, judging whether the first real-time temperature is greater than or equal to a final target temperature value, if so, enabling all N heating areas to pass through a multi-round circulating time-sharing heating process to reach the final target temperature value, and executing the step S7; if not, increasing the time-sharing target temperature value according to a second preset rule, and returning to execute the step S4.

And S7, keeping the N heating zones at the final target temperature value continuously. In some embodiments, all heating zones may be heated constantly at regular intervals to ensure that the heating zones are kept at the final target temperature.

In order to better set the time-sharing target temperature value, step S3 includes:

and acquiring second real-time temperature values of the N heating zones, calculating the temperature average value of the N heating zones according to the second real-time temperature values, and adding the temperature average value to the first preset value to obtain a time-sharing target temperature value. That is, in step S3, the initial time-sharing target temperature value calculation formula is as follows:

wherein T is _f Is a time-sharing target temperature value, T ₂ Is a second real-time temperature value, T _x Is a first preset value.

In order to enable the temperature of each heating area to reach the approximate temperature as soon as possible and provide a good heating experience, step S4 includes: and preferentially heating the heating group comprising the heating zone with the lowest second real-time temperature value. For example, the heating zone S1 is in the group 1, and the second real-time temperature value of the heating zone S1 is the lowest among all N heating zones, in the cyclic time-sharing heating performed in this round, even if the second real-time temperature values of other heating zones in the heating zone 1 are higher, the heating zone 1 including the heating zone S1 is preferentially selected to be heated, and then the heating group including the heating zone with the second real-time temperature value being the second lowest, the heating group including the heating zone with the second real-time temperature value being the third lowest, … … until the heating group including the heating zone with the second real-time temperature value being the highest, are sequentially heated.

In order to optimize the heating control, reduce the load of the power supply, and improve the efficiency of the grouped heating, each heating group shares a time slice independently in step S4. For example, in one time slice (a time slice refers to a time slice in which the operation time is divided into a plurality of time periods of fixed time length), heating is performed only on the heating areas in the selected heating group. That is, even if the heating zones in the heating group do not heat up due to a failure or other preset rules during the time slice, other heating groups or some heating zones in other heating groups do not heat up. A time slice is only used for the operation of the heating group corresponding to the time slice.

For the ordered heating of each heating group, step S4 comprises:

s401, let i =1, j =1;

s402, heating the jth heating group in the ith time slice;

s403, judging whether j is equal to M, if yes, executing a step S5; if not, let i = i +1, j = j +1, and return to execute step S402.

For example, N =6,m =3; in this case, in the 1 st time slice, the 1 st heating group is heated, and if j =1 ≠ 3=M, i =2, j =2; in the 2 nd time slice, heating the 2 nd heating group, and judging that j =2 ≠ 3=M, i =3 and j =3; in the 3 rd time slice, the 3 rd heating group is heated, j =3= M is determined, and if N heating zones of all M heating groups have completed one round of time-sharing heating, the process proceeds to step S5.

In order to avoid that the heating is still continued after the time-sharing target temperature value is reached by the subarea, the step S4 comprises the following steps: and if the heating zones in each heating group reach the time-sharing target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

In order to gradually increase the periodic target temperature of the time-sharing target temperature value to the final target temperature value, if not, increasing the time-sharing target temperature value according to a second preset rule, and returning to execute step S4, including:

and adding the second preset value to the time-sharing target temperature value, and returning to execute the step S4.

For example, a second preset value, for example, 1 deg.c, is added to the initial time-sharing target temperature value set in step S3 to increase the time-sharing target temperature value.

In order to cope with different temperature loss conditions of different areas and enable all heating areas to still keep similar temperature for a long time after reaching the target temperature, the step S7 comprises:

s701, sequentially carrying out circulating time-sharing heating on the M heating groups;

s702, judging whether the third real-time temperatures of the N heating areas are greater than or equal to the final target temperature value or not, if so, executing the step S703; if not, executing step S701;

and S703, after the preset time interval, returning to execute the step S702.

For example, when all the heating zones are determined to reach the final target temperature value in step S6, the process does not return to step S1 to step S5, and at this time, if the heat of the heating zone is dissipated to the outside, the temperature of the heating zone will be decreased accordingly. If N =4,m =2, first heating the 1 st heating group in the 1 st time slice, heating the 2 nd heating group in the 2 nd time slice, and determining whether all 4 heating areas are greater than or equal to the final target temperature, if yes, after leaving the heating areas empty for a preset time, returning to the second round of circulating time-sharing heating, and if not, directly returning to execute the next time-sharing heating.

In some other embodiments, step S7 includes:

sequentially carrying out circulating time-sharing heating on the M heating groups, and keeping continuous execution; and if the heating zones in each heating group reach the final target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

The second embodiment of the present invention discloses a heating control system for a heating suit, the heating suit having N heating zones, N being equal to or greater than 2, comprising:

and the final target temperature value setting module is used for setting final target temperature values of the N heating zones.

And the grouping module is used for dividing the N heating zones into M heating groups, wherein M is more than or equal to 2 and less than or equal to N. N and M are integers.

And the time-sharing target temperature value setting module is used for obtaining a time-sharing target temperature value according to a first preset rule.

And the heating module is used for sequentially carrying out circulating time-sharing heating on the M heating groups. For example, each heating group heats exclusively one time slice, and all M heating groups heat in turn.

The first judging module is used for judging whether the first real-time temperature of the N heating areas reaches a time-sharing target temperature value or not, and if so, the second judging module is executed; if not, executing the heating module.

The second judgment module is used for judging whether the first real-time temperature reaches a final target temperature value or not, and if so, the constant temperature module is executed; if not, the improving module is executed, and the heating module is returned to be executed.

And the increasing module is used for increasing the time-sharing target temperature value according to a second preset rule. And adding a preset value on the basis of the current time-sharing target temperature value according to the current time-sharing target temperature value to obtain an improved time-sharing target temperature value.

And the constant temperature module is used for keeping the N heating zones at the final target temperature value continuously. In some embodiments, the thermostat module is used in some embodiments to allow all of the heating zones to be heated fixedly once every certain period of time, and allow the N heating zones to be kept at the final target temperature value. In some other embodiments, the constant temperature module is configured to perform cyclic time-sharing heating on the M heating groups in sequence with the final target temperature value as the time-sharing target temperature value, so that the N heating zones are kept at the final target temperature value.

In order to better set the time-sharing target temperature value, the time-sharing target temperature value setting module is further configured to:

and acquiring second real-time temperature values of the N heating zones, calculating the average temperature value of the N heating zones according to the second real-time temperature values, and adding the first preset value to the average temperature value to obtain a time-sharing target temperature value. That is, in step S3, the initial time-sharing target temperature value calculation formula is as follows:

wherein T is _f Is a time-sharing target temperature value, T _i Is a second real-time temperature value, T _x Is a first preset value.

In order to allow the temperature of the respective heating zones to reach the approximate temperature as quickly as possible, and to provide a good heating experience, the heating module is further configured to preferentially heat the heating group including the heating zone with the lowest second real-time temperature value.

In order to optimize heating control, reduce the load on the power supply, and improve the efficiency of group heating, each heating group shares a time slice during the execution of the heating module.

In order to improve the heating effect, the heating module further comprises the following secondary modules:

a secondary assignment module configured to let i =1, j =1;

the secondary heating module is used for heating the jth heating group in the ith time slice;

the secondary time-sharing judgment module is used for judging whether j is equal to M or not, and if so, the first judgment module is executed; if not, let i = i +1, j = j +1, and return to executing the secondary heating module.

For example, N =6,m =3; in this case, in the 1 st time slice, the 1 st heating group is heated, and if j =1 ≠ 3=M, i =2, j =2; in the 2 nd time slice, heating the 2 nd heating group, and judging that j =2 ≠ 3=M, i =3 and j =3; in the 3 rd time slice, the 3 rd heating group is heated, j =3= M is judged, and if N heating zones of all M heating groups have completed one round of time-sharing heating, the process proceeds to the execution of the first judgment module.

In order to avoid that the heating is continued after the time-sharing target temperature value is reached by any subarea, the heating module is also used for: and if the heating zones in each heating group reach the time-sharing target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

In order to gradually increase the time-sharing target temperature value, which is the periodic target temperature, to the final target temperature value, the increasing module is further configured to: and adding a second preset value to the time-sharing target temperature value, and returning to the execution of the heating module. For example, a second preset value, for example, 1 deg.c is added to the initial time-sharing target temperature value set as the time-sharing target temperature value, and the time-sharing target temperature value is increased.

In order to cope with different temperature loss conditions of different areas and enable all heating areas to still keep similar temperature for a long time after reaching the target temperature, the constant temperature module is also used for:

sequentially carrying out circulating time-sharing heating on the M heating groups; judging whether the third real-time temperatures of the N heating zones are greater than or equal to the final target temperature value, if so, performing cyclic time-sharing heating on the M heating groups in sequence at preset time intervals; if not, executing circulation time-sharing heating to the M heating groups in sequence.

For example, when all the heating zones are judged to reach the final target temperature value in the second judging module, at this time, if the heat of the heating zone is dissipated to the outside, the temperature of the heating zone will be decreased accordingly. If N =4,m =2, first, heating the 1 st heating group in the 1 st time slice, heating the 2 nd heating group in the 2 nd time slice, and determining whether all 4 heating areas are greater than or equal to the final target temperature, if yes, after leaving empty for a preset time, returning to the second round of circulating time-sharing heating, and if not, directly returning to execute the next time-sharing heating.

In some other embodiments, the constant temperature module is further configured to: sequentially carrying out circulating time-sharing heating on the M heating groups, and keeping continuous execution; and if the heating zones in each heating group reach the final target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

As shown in fig. 2 and fig. 3, a third embodiment of the present invention discloses a heating suit, which comprises a heating suit body 1, heating zones 2 disposed at various parts of the heating suit body 1, and a heating control system for the heating suit according to the second embodiment of the present invention.

In order to realize controllable cost and guarantee stable heating of the heating clothes, the heating zone 2 arranged on the heating clothes is pre-cut heating pieces with fixed sizes, and the heating pieces can be applied to the heating clothes with different sizes and styles, so that the application of a heating control system and a heating control method is not influenced by factors such as the design of the heating clothes model.

In order for the heating suit to be effectively powered, in some embodiments, the power supply device that powers the heating control system for the heating suit in the heating suit is a portable power supply, and the connection between the portable power supply and the heating suit is waterproof. In order to wash the heating suit body 1 without detaching the heating sheet, in other embodiments, the portable mobile power supply has a bluetooth function at the same time, and can wirelessly control each module in the heating control system for the heating suit.

FIG. 3 shows the circuit connection relationship of the heating zones 2 disposed on the heating suit body 1, wherein the plurality of heating zones 2 include a first heating zone R ₁ A second heating zone R ₂ A third heating zone R ₃ A fourth heating zone R ₄ … … Nth heating zone R _N And a corresponding first switch Q ₁ A second switch Q ₂ And a third switch Q ₃ And a fourth switch Q ₄ … … Nth switch Q _N And a power supply VCC electrically connected to each heating zone 2.

By implementing the invention, the following beneficial effects are achieved:

the invention provides a heating control method and system for a heating garment and the heating garment, wherein the heating control method for the heating garment is suitable for a heating system with N heating zones; setting a final target temperature value; dividing the N heating zones into M heating groups; obtaining a time-sharing target temperature value according to a first preset rule; sequentially carrying out circulating time-sharing heating on the M heating groups; if the temperatures of the N heating areas do not reach the time-sharing target temperature value, continuing to circularly heat in a time-sharing manner; if the temperatures of the N heating areas reach the time-sharing target temperature value but do not reach the final target temperature value, increasing the time-sharing target temperature value according to a second preset rule, and continuing to circularly heat in a time-sharing manner; and after the final target temperature value is reached, keeping the constant temperature of the N heating zones. The invention adopts zone heating and groups the heating zones, thereby saving the power supply pressure of a power supply, improving the comfort level of a user and continuously keeping the temperature constant after reaching the preset target temperature.

According to the invention, the time-sharing target temperature value is obtained according to the first preset rule, the temperature difference between the heating zones is reduced as much as possible, and the condition that a user using the heating suit cannot feel cold and the like caused by overlarge temperature difference between the heating zones is ensured. According to the invention, the time-sharing target temperature value is increased according to the second preset rule, and then the heating zones are subjected to grouped cyclic time-sharing heating, so that the heating clothes are stably heated in the heating process, the user feeling is mild, the power supply load is small, and the effect is good.

It is to be understood that the foregoing examples, while indicating the preferred embodiments of the invention, are given by way of illustration and description, and are not to be construed as limiting the scope of the invention; it should be noted that, for those skilled in the art, the above embodiments or technical features can be freely combined, and several modifications and improvements can be made without departing from the concept of the present invention, which all belong to the protection scope of the present invention, that is, the embodiments described in "some embodiments" can be freely combined with any of the above and below embodiments; therefore, all equivalent changes and modifications made within the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. A heating control method for heating clothes is characterized by being suitable for a heating system with N heating zones, wherein N is more than or equal to 2, and the method comprises the following steps:

s1, setting final target temperature values of the N heating zones;

s2, dividing the N heating zones into M heating groups, wherein M is more than or equal to 2 and less than or equal to N;

s3, obtaining a time-sharing target temperature value according to a first preset rule;

s4, sequentially carrying out circulating time-sharing heating on the M heating groups;

s5, judging whether the first real-time temperatures of the N heating zones are larger than or equal to the time-sharing target temperature value or not, and if so, executing a step S6; if not, executing the step S4;

s6, judging whether the first real-time temperature is greater than or equal to the final target temperature value, if so, executing a step S7; if not, increasing the time-sharing target temperature value according to a second preset rule, and returning to execute the step S4;

and S7, keeping the N heating zones at the final target temperature value continuously.

2. The heating control method for heating clothes according to claim 1, wherein the step S3 includes:

and acquiring second real-time temperature values of the N heating zones, calculating the temperature average value of the N heating zones according to the second real-time temperature values, and adding a first preset value to the temperature average value to obtain a time-sharing target temperature value.

3. The heating control method for heating clothes according to claim 2, wherein the step S4 includes: and preferentially heating the heating group comprising the heating zone with the lowest second real-time temperature value.

4. The heating control method for heating clothes according to claim 1, wherein in step S4, each of the heating groups shares a time slice.

5. The heating control method for heating clothes according to claim 4, wherein the step S4 includes:

s401, let i =1,j =1;

s402, heating the jth heating group in the ith time slice;

s403, judging whether j is equal to M, if yes, executing a step S5; if not, let i = i +1, j = j +1, and return to execute step S402.

6. The heating control method for heating clothes according to claim 4, wherein the step S4 includes: and if the heating zones in each heating group reach the time-sharing target temperature value, the heating zones are not heated in the current time slice, and the next time slice is waited.

7. The heating control method for heating clothes according to claim 1, wherein in step S6, if not, increasing the time-sharing target temperature value according to a second preset rule, and returning to perform step S4 includes:

and adding a second preset value to the time-sharing target temperature value, and returning to execute the step S4.

8. The heating control method for heating clothes according to claim 1, wherein the step S7 includes:

s701, sequentially carrying out circulating time-sharing heating on the M heating groups;

s702, judging whether the third real-time temperatures of the N heating zones are greater than or equal to the final target temperature value, if so, executing a step S703; if not, executing step S701;

and S703, after the preset time interval, returning to execute the step S702.

9. A heating control system for a heating garment, the heating garment having N heating zones, N being greater than or equal to 2, comprising:

the final target temperature value setting module is used for setting final target temperature values of the N heating zones;

the grouping module is used for dividing the N heating zones into M heating groups, wherein M is more than or equal to 2 and less than or equal to N;

the time-sharing target temperature value setting module is used for obtaining a time-sharing target temperature value according to a first preset rule;

the heating module is used for sequentially carrying out circulating time-sharing heating on the M heating groups;

the first judging module is used for judging whether the first real-time temperature of the N heating areas reaches the time-sharing target temperature value or not, and if so, the second judging module is executed; if not, executing a heating module;

the second judgment module is used for judging whether the first real-time temperature reaches the final target temperature value or not, and if so, the constant temperature module is executed; if not, executing the improving module, and returning to execute the heating module;

the increasing module is used for increasing the time-sharing target temperature value according to a second preset rule;

and the constant temperature module is used for enabling the N heating zones to be continuously kept at the final target temperature value.

10. A heating suit comprising a heating suit body and heating zones provided at respective portions of the heating suit body, characterized by further comprising the heating control system for a heating suit according to claim 9.

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