CN113741585A - Intelligent dynamic temperature control method based on personalized heat demand and intelligent heating clothes - Google Patents

Abstract

The invention provides an intelligent dynamic temperature control method based on individual heat demand and an intelligent heating garment. The heating of each heating area of the intelligent heating clothes is divided into a continuous heating temperature rise stage, an automatic regulation stage and a dynamic heating mode stage, each heating area is firstly set to be a target at a default temperature for rapid heating, the automatic regulation stage is started after the heating is carried out to the target temperature, a user can flexibly set heating parameters of each heating area, and therefore a parameter setting mode which is most suitable for meeting the personalized requirements of the user under the current situation is found, then dynamic circulation alternate heating is carried out, the thermal comfort state of the user can be maintained, the electric quantity consumption of a power supply can be greatly reduced, and the power supply time of the power supply is prolonged.

Description

Intelligent dynamic temperature control method based on personalized heat demand and intelligent heating clothes

Technical Field

The invention relates to the field of intelligent clothes and a temperature control method thereof, in particular to an intelligent dynamic temperature control method based on individual heat demand and an intelligent heating clothes.

Background

When people perform outdoor activities in winter, people need to wear thicker clothes to resist long-time cold exposure in outdoor environments, and changes of cold and hot feelings in outdoor activities are met by adding or reducing clothes. However, heavy garments for keeping warm often result in inconvenience to the person and greatly affect the aesthetic appearance of the garment. The introduction of the active heating material can effectively make up the defects of passive heat-insulation clothes, and the clothes with the active heating function can be lighter, thinner and more attractive under the condition that the same heat feeling level of a human body is maintained in the same cold environment, and the function of autonomous temperature adjustment is more convenient and effective compared with increasing and decreasing clothes.

Through the performance of the heating clothing of contrast electrical heating clothing and other forms, electrical heating clothing regulation and control has more timeliness, accurate nature, and electrical heating system can realize under the prerequisite of light relatively, has better promotion effect to clothing winter protection ability. And along with the development of the society, the electric heating clothes also meet the requirements of personalized and intelligent development. Therefore, thanks to the rapid development of information technology, the electric heating clothes become the mainstream products in the existing heating clothes market and are generally applied. However, the electrical heating clothes in the prior art lack a good temperature control system and are highly dependent on manual adjustment of a user, and personalized adjustment based on self-thermal characteristics of the user cannot be realized.

In addition, for intelligent electrically heated garments, the contradiction between battery weight and electrical capacity (power supply time) has not been solved well. The existing product still has the defects of very limited single-charging use time, larger self-generating limit, heavy battery weight, inconvenience in carrying and the like. After the currently equipped intelligent temperature control system finishes a temperature control target, the system usually enters a continuous and constant heating state, the energy consumption is high, and the electric capacity of a power supply is greatly challenged. Therefore, there is a need in the art for an intelligent temperature control garment and a temperature control method that can ensure a good heat supply effect based on individual unique requirements and that are environmentally friendly and energy-saving.

Disclosure of Invention

Aiming at the defects and shortcomings of the prior art, the invention provides an intelligent dynamic temperature control method based on personalized heat requirements, the method is used for temperature control of intelligent heating clothes, the intelligent heating clothes is provided with a plurality of heating areas, the heating areas correspond to different parts to be heated of a human body, the intelligent heating clothes is further provided with an interactive panel, and the method comprises the following steps:

s1, starting the heating modules of the heating areas of the intelligent heating garment, and enabling the heating modules of the heating areas to start continuous heating and temperature rise by taking default temperature setting T1 as a target;

s2, after the temperature of each heating area reaches the target temperature T1, starting an automatic adjusting stage, and enabling a user to automatically select the start-stop and/or temperature setting T2 of different heating areas through an interactive panel;

s3: judging and analyzing whether the user reaches a thermal comfort state, if so, entering a substep S31, and if not, continuing to wait and analyze and judge until the user reaches the thermal comfort state; wherein the substep S31 specifically includes the following steps:

s311: recording the setting of the heating state of each heating area at the moment, wherein the setting comprises one or more of a start-stop state, a heating temperature setting and a user external environment parameter;

s312: creating and naming a scenized comfort mode for the current settings;

s313: end step S3, and proceed to step S4;

s4: and after the current scene comfort mode is judged to reach a certain time threshold value after being established, the dynamic heating mode is entered, and each heating area is enabled to carry out dynamic circulation alternate heating by setting the parameters in the current scene comfort mode as targets.

Further, the default temperature setting T1 of the heating modules of the respective heating zones is the same or different, and the specific value of T1 is a default value or is set by the user.

Further, the method for determining whether the user has reached the thermal comfort state in step S3 specifically includes:

s31, when the autonomous adjusting stage lasts 15 minutes and the user does not have adjusting action within 10-15 minutes, judging that the user reaches a thermal comfort state;

s32, when the autonomous adjusting stage lasts 15 minutes and the user has an adjusting action within 10-15 minutes, judging that the user does not reach a thermal comfort state;

s33, when the user is judged that the thermal comfort state is not reached, the time point when the user takes the adjusting action is taken as the initial time point for re-timing;

s34, when the system counts again and the time is 5 minutes and the user has no adjusting action within 5 minutes, judging that the user reaches the thermal comfort state;

and S35, when the system counts again and then takes 5 minutes, but the user has adjustment action within 5 minutes, judging that the user does not reach the thermal comfort state, repeating the step S33, and continuing to wait, analyze and judge.

Furthermore, after the heating modules of each heating area reach the default temperature setting T1, the autonomous adjusting stage is entered, and the adjusting authority of each heating area is opened.

Further, the scenized comfort mode created and named in step S312 includes the following information: the name of the mode, user information, the external environment temperature and humidity of the user, the starting and stopping states of the heating modules of each heating area, and the set value of the heating temperature of the heating module in the starting state.

Further, in step S4, the heating modules of the heating zones are cyclically and alternately heated in groups, and the groups of the heating modules are default or set by the user.

Further, the cyclic alternating heating in step S4 is performed with a period of time, which is a time taken for the heating modules of all the heating regions to be heated once.

Further, the period is default or set by a user.

Further, the period is 3 minutes.

The invention also provides intelligent heating clothes which are provided with a plurality of heating areas, the heating areas correspond to different parts of a human body to be heated, the intelligent heating clothes are also provided with an interactive panel, and the heating clothes are controlled by the method.

The invention can realize the following technical effects:

1. aiming at the defect that the existing intelligent heating clothes cannot meet individual differential thermal comfort requirements of users, an interactive panel is arranged on the heating clothes, so that the users can freely select the on-off states and temperature settings of different heating modules in different heating areas through the interactive panel, and the personalized thermal comfort requirements of the users are met to the greatest extent;

2. the intelligent heating clothes heating method comprises a continuous heating temperature-rising stage, an automatic adjusting stage and a dynamic heating mode stage, wherein each heating region is set to be a target at a default temperature and is rapidly heated, the automatic adjusting stage is started after the heating temperature reaches the target temperature, so that a user can flexibly set heating parameters of each heating region, a parameter setting mode which is most suitable for meeting the personalized requirements of the user under the current situation is found, then the heating is performed in a dynamic circulation and alternative mode, the thermal comfort state of the user can be maintained, the power consumption of a power supply can be greatly reduced, and the power supply time of the power supply is prolonged.

3. According to the invention, the external environment parameters of the user are collected, and the corresponding scene comfort mode is established according to the personalized heat comfort requirement of the user, so that the subsequent intelligent heating clothes with similar scenes can respond to the heat requirement of the user in time by adopting the memorized comfort mode, repeated adjustment is avoided, and the design requirements of intellectualization, personalization and convenience are met.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings that are needed in the embodiments or the prior art descriptions will be briefly described below.

FIG. 1 is a schematic flow chart of a method disclosed in embodiment 1 of the present invention.

Fig. 2 is a schematic structural diagram of an intelligent heating suit disclosed in embodiment 2 of the present invention.

Fig. 3 is a schematic view of the components of the intelligent heating suit disclosed in embodiment 2 of the present invention.

Detailed Description

The invention will now be described in further detail with reference to the accompanying drawings, which are provided solely for a better understanding of the invention and are not to be construed as limiting the invention. All other embodiments, which can be derived by a person skilled in the art from the patented embodiments of the invention without any inventive step, are within the scope of protection of the invention.

In the description of the present invention, it should be noted that, as the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. appear, their indicated orientations or positional relationships are based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second," if any, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" should be interpreted broadly, e.g., as being fixed or detachable or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

The embodiment discloses an intelligent dynamic temperature control method based on personalized heat demand, which is used for temperature control of an intelligent heating garment, wherein the intelligent heating garment is provided with a plurality of heating areas, the heating areas correspond to different parts to be heated of a human body, and the intelligent heating garment is further provided with an interaction panel. As shown in connection with fig. 1, the method comprises the steps of:

s1, starting the heating modules of the heating areas of the intelligent heating garment, and enabling the heating modules of the heating areas to start continuous heating and temperature rise by taking default temperature setting T1 as a target;

s2, after the temperature of each heating area reaches the target temperature T1, starting an automatic adjusting stage, and enabling a user to automatically select the start-stop and/or temperature setting T2 of different heating areas through an interactive panel;

s3: judging and analyzing whether the user reaches a thermal comfort state, if so, entering a substep S31, and if not, continuing to wait and analyze and judge until the user reaches the thermal comfort state; wherein the substep S31 specifically includes the following steps:

s311: recording the setting of the heating state of each heating area at the moment, wherein the setting comprises one or more of a start-stop state, a heating temperature setting and a user external environment parameter;

s312: creating and naming a scenized comfort mode for the current settings;

s313: end step S3, and proceed to step S4;

s4: and after the current scene comfort mode is judged to reach a certain time threshold value after being established, the dynamic heating mode is entered, and each heating area is enabled to carry out dynamic circulation alternate heating by setting the parameters in the current scene comfort mode as targets.

Specifically, in the step S1, the default temperature setting T1 of the heating module of each heating zone is the same or different, and the specific value of T1 is a default value or is set by the user. In an optimized embodiment, the default temperature setting T1 for each heating zone is 32 ℃. This value is merely an example and does not limit the scope of the invention. This selection of temperature setting can be adjusted as desired, with a low value being the intelligent heating suit likely to enter the autonomous phase earlier, but the longer and more subject to fluctuations the time required to reach the thermal comfort state, and a high value being the autonomous phase opened later, but likely to reach the thermal comfort state faster.

Specifically, the method for determining whether the user has reached the thermal comfort state in step S3 includes:

s31, when the autonomous adjusting stage lasts 15 minutes and the user does not have adjusting action within 10-15 minutes, judging that the user reaches a thermal comfort state;

s32, when the autonomous adjusting stage lasts 15 minutes and the user has an adjusting action within 10-15 minutes, judging that the user does not reach a thermal comfort state;

s33, when the user is judged that the thermal comfort state is not reached, the time point when the user takes the adjusting action is taken as the initial time point for re-timing;

s34, when the system counts again and the time is 5 minutes and the user has no adjusting action within 5 minutes, judging that the user reaches the thermal comfort state;

and S35, when the system counts again and then takes 5 minutes, but the user has adjustment action within 5 minutes, judging that the user does not reach the thermal comfort state, repeating the step S33, and continuing to wait, analyze and judge.

It is understood that the time length in steps S31 to S35 is only an example and does not limit the scope of the present invention, and those skilled in the art can adjust the time length according to actual situations, and the time length can also be set and selected by the user to meet the personalized needs of the user to the greatest extent. This step may be understood as an observation of the user's behavior of selecting and adjusting the temperature setting, and generally speaking, if the user does not change the temperature setting for a long time, or does not continue to adjust the setting for a while after the change, the user may be considered satisfied with the current situation and a thermal comfort state has been achieved.

In a specific embodiment, the autonomous adjusting stage may be started after the default temperature setting T1 is reached, but in an optimized embodiment, the heating modules of the heating zones jointly enter the autonomous adjusting stage after the default temperature setting T1 is reached, and the adjusting authority of each heating zone is opened.

The scenized comfort mode created and named in said step S312 contains the following information: the name of the mode, user information, the external environment temperature and humidity of the user, the starting and stopping states of the heating modules of each heating area, and the set value of the heating temperature of the heating module in the starting state. It will be appreciated that the above information is not exhaustive and that one skilled in the art may also record other information deemed relevant as necessary to better reproduce the scene and match the current parameter settings.

Specifically, in step S4, the heating modules in the heating zones are cyclically and alternately heated in groups, and the groups of the heating modules are default or set by the user. For example, a group of heating modules of a certain heating area may be used, or a group of heating modules of a certain heating area may be used, and when it is time for a certain group of heating modules to start heating, the heating modules in the group start heating together.

Specifically, the cyclic alternating heating in step S4 is performed with a period of time, which is the time taken for the heating modules of all the heating regions to heat once. The period is default or set by the user, for example the period is 2-5 minutes, in an optimized embodiment the period is default and set to 3 minutes. It is understood that the numerical values are only examples, and those skilled in the art can flexibly select the numerical values according to actual situations. The longer the period is, the longer the time for heating each heating region once is, so that energy consumption caused by the regulation and control process is reduced, and a certain effect is achieved on saving battery power consumption, but the temperature of each heating region is obviously reduced, the energy consumption for subsequent temperature rise of a user is relatively increased, the shorter the period is, the smaller the temperature fluctuation of each heating region is, the more comfortable the user feels, and the consumption of the battery is not necessarily correspondingly increased.

The beneficial effect that this embodiment can realize is:

1. according to the intelligent dynamic temperature control method based on the personalized heat demand and the intelligent heating clothes, aiming at the defect that the existing intelligent heating clothes cannot meet the individual differentiated heat comfort demand of a user, an interactive panel is arranged on the heating clothes, so that the user can freely select the on-off state and the temperature setting of different heating modules in different heating areas through the interactive panel, and the personalized heat comfort demand of the user is met to the greatest extent;

2. the intelligent heating clothes heating method comprises a continuous heating temperature-rising stage, an automatic adjusting stage and a dynamic heating mode stage, wherein each heating region is set to be a target at a default temperature and is rapidly heated, the automatic adjusting stage is started after the heating temperature reaches the target temperature, so that a user can flexibly set heating parameters of each heating region, a parameter setting mode which is most suitable for meeting the personalized requirements of the user under the current situation is found, then the heating is performed in a dynamic circulation and alternative mode, the thermal comfort state of the user can be maintained, the power consumption of a power supply can be greatly reduced, and the power supply time of the power supply is prolonged.

3. The method can collect the external environment parameters of the user, and create the corresponding scene comfort mode according to the personalized heat comfort requirement of the user, so that the subsequent intelligent heating clothes with similar scenes can respond to the heat requirement of the user in time by adopting the memorized comfort mode, repeated adjustment is avoided, and the design requirements of intellectualization, personalization and convenience are met.

Example 2

The embodiment discloses an intelligent heating suit, which is provided with a plurality of heating areas, wherein the heating areas correspond to different parts of a human body to be heated, and an interaction panel, and the heating suit is controlled by using the method in embodiment 1.

Specifically, as shown in fig. 2, the intelligent heating garment includes a garment body and a microprocessor disposed in the garment body, and each heating area has a corresponding heating module, a plurality of temperature sensors, a single temperature and humidity monitoring button, and the like.

The temperature sensor is used for acquiring real-time temperatures of the heating modules of the heating regions, and the single temperature and humidity monitoring buckle is used for acquiring the temperature and humidity of the external environment of the user.

The interaction panel can be a button on the intelligent heating clothes, an electronic display screen or a mobile phone APP of a user. When interactive panel is the button, can set up control button in the clothes inlayer, this control button and microprocessor, microprocessor includes charge and discharge circuit and pulse width modulation circuit, and when cold and hot demand changes, the inboard control button of wearer's accessible clothes opens from the main control heating and stops, adjusts heating power, removes the trouble of increase and decrease clothing from, and the response is rapid, and it is convenient to use.

When the interaction panel is a mobile phone APP, the intelligent heating clothes are provided with the wireless communication module for receiving instructions of the user side, and the user can start the equipment, set the temperature of each heating area and the like through the mobile phone APP, so that the human-computer interaction function is realized.

The heating module of each heating region carries out the initiative heating to the human body, specifically carries out the even blending for graphene fiber and fabric surface fabric and makes flexible graphite alkene blending electric heat piece, and the embedding design in the clothes intermediate layer, has compromise the wearing comfort of user and the heating efficiency of intelligent heating clothes, and its compliance, travelling comfort and the washability of existing fabric can guarantee again in low temperature environment that the effect is rapid, it is even to generate heat, and its distinctive far infrared function can effectively relax the muscle, alleviate fatigue.

The micro-processor is respectively and electrically connected with the plurality of temperature sensors, the rechargeable battery, the wireless communication module and the heating module, and is used for selectively controlling the operating power of the heating module through a PID algorithm according to a target temperature and an operating mode, controlling the starting and stopping states of the heating module through on-off control, storing the working state of the heating module through an internal memory unit and the like.

The clothes body is used as a base body of the intelligent heating clothes and used for bearing a system and passively insulating a human body, and the clothes body is respectively provided with a windproof and waterproof outer layer fabric, a heat insulation layer, a graphene blended electric heating piece and an inner layer fabric from outside to inside, as shown in figure 3.

Preferably, the wireless communication module adopts a Bluetooth communication technology;

optionally, the thermal insulation layer comprises aerogel or a stacked state;

optionally, the inner shell fabric comprises a fleece fabric or a pure cotton liner;

optionally, the method further comprises: and the battery module is used for providing electric energy for the intelligent heating clothes.

Preferably, the dynamic heating mode simultaneously starts the control unit, the start/stop unit and the memory unit of the microprocessor 4, the memory unit is used for storing information and setting parameters of the scene comfort mode, the start/stop unit is used for regularly starting/stopping the heating module of the corresponding heating area and linking the starting instruction with the control unit, and the control unit is used for controlling the heating module in the starting state to the heating temperature set value of the heating module in the comfort mode stored in the memory unit.

The embodiment can achieve the following technical effects:

according to the invention, the surface temperature is raised by using the stored electric energy of the flexible graphene electric heating film placed in the interlayer of the garment, and the part of the human body in direct contact is locally heated in a heat conduction manner, so that the heat preservation performance of the garment is greatly improved. The heating power of the flexible graphene electric heating film can be regulated and controlled through the control unit of the micro-processor according to the heating temperature set by the user side, so that the dynamic individual heating requirement is met, and the thermal comfort of wearing is guaranteed in the outdoor low-temperature environment. Meanwhile, a scene comfortable mode is established by using the wireless communication module and the memory unit of the microprocessor, and the dynamic heating mode after the heating temperature target is reached is used for prolonging the service time under the condition of certain power capacity by reducing the heating output power in unit time, so that the requirement of power supply time is effectively met.

The above embodiments are only used for explaining the present invention, and the structure, connection mode, manufacturing process, etc. of the components may be changed, and all equivalent changes and modifications performed on the basis of the technical solution should not be excluded from the protection scope of the present invention.

Claims (14)

1. An intelligent dynamic temperature control method based on personalized heat demand is used for temperature control of an intelligent heating garment, the intelligent heating garment is provided with a plurality of heating areas, the heating areas correspond to different parts to be heated of a human body, the intelligent heating garment is further provided with an interaction panel, and the intelligent heating garment is characterized in that: the method comprises the following steps:

s1, starting the heating modules of the heating areas of the intelligent heating garment, and enabling the heating modules of the heating areas to start continuous heating and temperature rise by taking default temperature setting T1 as a target;

s2, after the temperature of each heating area reaches the target temperature T1, starting an automatic adjusting stage, and enabling a user to automatically select the start-stop and/or temperature setting T2 of different heating areas through an interactive panel;

s3: judging and analyzing whether the user reaches a thermal comfort state, if so, entering a substep S31, and if not, continuing to wait and analyze and judge until the user reaches the thermal comfort state; wherein the substep S31 specifically includes the following steps:

s311: recording the setting of the heating state of each heating area at the moment, wherein the setting comprises one or more of a start-stop state, a heating temperature setting and a user external environment parameter;

s312: creating and naming a scenized comfort mode for the current settings;

s313: end step S3, and proceed to step S4;

s4: and after the current scene comfort mode is judged to reach a certain time threshold value after being established, the dynamic heating mode is entered, and each heating area is enabled to carry out dynamic circulation alternate heating by setting the parameters in the current scene comfort mode as targets.

2. The method of claim 1, wherein: the default temperature settings T1 for the heating modules for the respective heating zones are the same or different, and the specific value of T1 is a default value or is set by the user.

3. The method of claim 1, wherein: the method for determining and analyzing whether the user has reached the thermal comfort state in step S3 specifically includes:

s31, when the autonomous adjusting stage lasts 15 minutes and the user does not have adjusting action within 10-15 minutes, judging that the user reaches a thermal comfort state;

s32, when the autonomous adjusting stage lasts 15 minutes and the user has an adjusting action within 10-15 minutes, judging that the user does not reach a thermal comfort state;

s33, when the user is judged that the thermal comfort state is not reached, the time point when the user takes the adjusting action is taken as the initial time point for re-timing;

s34, when the system counts again and the time is 5 minutes and the user has no adjusting action within 5 minutes, judging that the user reaches the thermal comfort state;

and S35, when the system counts again and then takes 5 minutes, but the user has adjustment action within 5 minutes, judging that the user does not reach the thermal comfort state, repeating the step S33, and continuing to wait, analyze and judge.

4. The method of claim 1, wherein: and when the heating modules of all the heating areas reach the default temperature setting T1, entering an autonomous adjusting stage, and opening the adjusting permission of all the heating areas.

5. The method of claim 1, wherein: the scenized comfort mode created and named in the step S312 includes the following information: the name of the mode, user information, the external environment temperature and humidity of the user, the starting and stopping states of the heating modules of each heating area, and the set value of the heating temperature of the heating module in the starting state.

6. The method of claim 1, wherein: the heating modules of the heating zones in the step S4 perform grouped cyclic alternate heating, and the grouping of the heating modules is default or set by the user.

7. The method of claim 1, wherein: the cyclic alternating heating in step S4 is performed for a period of time taken for the heating modules of all the heating regions to heat once.

8. The method of claim 7, wherein: the period is default or set by the user.

9. The method of claim 7, wherein: the period was 3 minutes.

10. The utility model provides an intelligence heating clothes, its has a plurality of heating region, a plurality of heating region is corresponding to human different portions of heating of treating, intelligence heating clothes still has interactive panel, its characterized in that: the heating suit is controlled using the method of any one of claims 1 to 9.

11. The intelligent heating suit of claim 10, wherein: the intelligent heating clothes comprise a clothes body and a microprocessor arranged in the clothes body, and each heating area is provided with a corresponding heating module; the intelligent heating clothes are also provided with a plurality of temperature sensors and a single temperature and humidity monitoring buckle.

12. The intelligent heating suit of claim 10, wherein: the interaction panel is a button on the intelligent heating clothes or a mobile phone APP of a user.

13. The intelligent heating garment of claim 10, wherein the heating module is a flexible graphene blended electric heating sheet made by uniformly blending graphene fibers and fabric.

14. The intelligent heating suit of claim 11, wherein: the clothes body comprises a windproof and waterproof outer-layer fabric, a heat insulation layer, a graphene blended electric heating piece and an inner-layer fabric from outside to inside; wherein the thermal insulation layer comprises aerogel or a stacked state.

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