TWI721749B - Moisture control cloth and control method thereof - Google Patents

Abstract

A moisture control cloth including a sensing module, a moisture control module and a control device is provided. The sensing module is disposed on an inner side of the moisture control cloth, and the sensing module includes a temperature sensor. The moisture control module is disposed between a hem and a collar of the moisture control cloth. The moisture control module includes a first porous electrode layer, a moisture control layer, and a second porous electrode layer, wherein the moisture control layer is disposed between the first porous electrode layer and the second porous electrode layer. The control device is electrically connected to the temperature sensor and the first porous electrode layer and the second porous electrode layer. The sensing module is located at a bust of the moisture control cloth and adjacent to a neckline thereof.

Description

Humidity adjusting clothing and its control method

The content of this disclosure relates to an adjusted clothing and a control method thereof, and particularly relates to a humidity adjustment clothing and a control method thereof.

Among wearable electronic devices for physiological monitoring, electronic devices such as electronic bracelets and smart watches can measure and monitor the user's physiological information by touching the skin. However, these electronic devices can only unilaterally obtain physiological information from the user, and cannot actively adjust the user's use environment.

As people's demands for health management, physiological monitoring, motor function and other functions continue to increase, how to further adjust the user's use environment based on physiological information is still a problem to be solved in this field.

Embodiments of the present disclosure provide a humidity adjustment garment, which includes a sensing module, a humidity adjustment module, and a control element. The sensing module is arranged on the inner side of the humidity adjustment clothing, and the sensing module includes a temperature sensor. The humidity adjustment module is arranged between the hem and the collar of the humidity adjustment clothing. The humidity adjustment module includes a first porous electrode layer, a humidity control layer, and a second porous electrode layer. The first porous electrode layer is adjacent to the inside of the humidity adjustment garment, the second porous electrode layer is adjacent to the outside of the humidity adjustment garment, and the humidity control layer is located between the first porous electrode layer and the second porous electrode layer. The control element is electrically connected to the temperature sensor of the sensing module and the first porous electrode layer and the second porous electrode layer of the humidity adjustment module. The sensing module is located on the bust of the humidity-adjusting apparel and adjacent to the neckline of the humidity-adjusting apparel.

In some embodiments, the aforementioned sensing module includes a humidity sensor electrically connected to the control element.

In some embodiments, the aforementioned sensing module includes a heart rhythm sensor, which is electrically connected to the control element.

In some embodiments, the above-mentioned humidity adjustment apparel further includes a wind speed sensor, which is electrically connected to the control element. The position of the wind speed sensor is arranged on the front part of the humidity-adjusting clothing and adjacent to the shoulder stitch of the humidity-adjusting clothing.

In some embodiments, the above-mentioned humidity adjustment module is adjacent to the hem of the humidity adjustment apparel.

In some embodiments, the aforementioned humidity adjustment module is adjacent to the chest circumference of the humidity adjustment apparel, and the position of the humidity adjustment module corresponds to the user's pectoralis major or trapezius muscle.

In some embodiments, the above-mentioned humidity adjustment apparel further includes a connecting opening and a connecting structure. The connecting opening is arranged between the hem and the collar of the humidity adjustment apparel. The connecting structure is arranged at the inner edge of the connecting opening, and the connecting structure detachably connects the humidity adjustment module to the connecting opening.

The embodiment of the present disclosure provides a humidity adjustment clothing The control method includes: obtaining the first physiological information from the sensing module, and when the first physiological information meets the judgment threshold, the control element causes the humidity adjustment module to switch from the heat preservation mode to the humidity adjustment mode; and obtaining the second physiological information Information, the control element adjusts the control signal in the humidity adjustment mode according to the second physiological information. In the humidity adjustment mode, the humidity adjustment module increases the penetration rate of moisture from the inside to the outside of the humidity adjustment garment. In the heat preservation mode, the humidity adjustment module reduces the penetration rate of moisture from the inside to the outside.

In some embodiments, the above-mentioned first physiological information includes humidity adjustment of the temperature or humidity in the clothing.

In some embodiments, the aforementioned second physiological information includes the user's age, the user's heart rhythm, or the environmental wind speed.

In some embodiments, the step of adjusting the control signal of the humidity adjustment module in the humidity adjustment mode by the control element according to the second physiological information includes: adjusting the period, frequency, or pulse width of the control signal.

d1‧‧‧direction

S11, S12, S13, S14, S15‧‧‧Step

100, 200‧‧‧Humidity adjustment clothing

101, 201‧‧‧Bust

102‧‧‧Neckline

103、203‧‧‧Collar

104、204‧‧‧Clothes

105、106‧‧‧surface

110, 210, 210A‧‧‧sensing module

112, 212‧‧‧Temperature sensor

120‧‧‧Control components

121‧‧‧Wireless Transmission Module

130, 230, 234‧‧‧Humidity adjustment module

131、231‧‧‧First porous electrode layer

132, 232‧‧‧Humidity control layer

133、233‧‧‧Second porous electrode layer

207‧‧‧Front garment piece

208‧‧‧Back garment piece

209‧‧‧Shoulder stitch

2010‧‧‧Front shoulder

214‧‧‧Humidity Sensor

215‧‧‧Temperature and Humidity Sensor

216‧‧‧Heart Rhythm Sensor

216A‧‧‧Light source

216B‧‧‧Camera unit

220‧‧‧Control components

240‧‧‧Wind speed sensor

250‧‧‧Connecting opening

251‧‧‧Connecting structure

5-5、8-8‧‧‧Cutting line

Figure 1 is a block diagram of the humidity adjustment clothing in an embodiment of the present disclosure;

Figure 2 is a schematic cross-sectional view of a humidity adjustment module in an embodiment of the disclosure;

Figure 3 is a three-dimensional schematic diagram of the humidity adjustment clothing in an embodiment of the present disclosure;

Figure 4 is a schematic diagram of a sensing module in an embodiment of the present disclosure;

Figure 5 is a schematic cross-sectional view drawn according to the cutting line 5-5 in Figure 3;

FIG. 6 is a schematic flowchart of a method for controlling humidity adjustment clothing according to an embodiment of the present disclosure;

FIG. 7A and FIG. 7B are three-dimensional schematic diagrams of humidity adjustment clothing according to another embodiment of the present disclosure;

Figure 8 is a schematic cross-sectional view drawn according to the section line 8-8 in Figure 7A;

FIG. 9 is a schematic diagram of a sensing module in an embodiment of the disclosure;

FIG. 10 is a schematic diagram of a sensing module in still another embodiment of the present disclosure.

In the following, multiple implementations of the content will be disclosed in schematic form. For the sake of clarity, many practical details will be described in the following description. However, it should be understood that these practical details should not be used to limit the content of this disclosure. That is to say, these practical details are unnecessary in the implementation of this disclosure. In addition, in order to simplify the drawings, some conventionally used structures and elements will be shown in a simple schematic manner in the drawings.

The humidity adjustment clothing contained in the present disclosure includes a humidity adjustment module, so the humidity can be adjusted to adjust the humidity of the inside and outside of the clothing. The humidity adjustment clothing also includes a sensing module, which can obtain physiological information of the user. The method for controlling the humidity adjustment clothing of the present disclosure obtains the first physiological information and the second physiological information from the sensing module, and then controls the humidity adjustment module according to the first physiological information and the second physiological information.

FIG. 1 is a block diagram of a clothing with humidity adjustment in an embodiment of the present disclosure. Please refer to FIG. 1, in an embodiment of the present disclosure, the humidity adjustment apparel 100 includes a sensing module 110, a humidity adjustment module 130 and a control element 120. The sensing module 110 includes a temperature sensor 112. The humidity adjustment module 130 includes a first porous electrode layer 131, a second porous electrode layer 133, and a The humidity control layer 132 between the porous electrode layer 131 and the second porous electrode layer 133. The control element 120 is electrically connected to the temperature sensor 112 of the sensing module 110 and the first porous electrode layer 131 and the second porous electrode layer 133 of the humidity adjustment module 130.

Specifically, in the humidity adjustment apparel 100 of this embodiment, the control element 120 can obtain temperature data from the temperature sensor 112 of the sensing module 110, and can also provide a control signal to the first porous electrode layer 131 and The second porous electrode layer 133. For example, the control element 120 may provide a signal with a high potential to the first porous electrode layer 131 and a signal with a low potential to the second porous electrode layer 133, so that the first porous electrode layer 131 and the second porous electrode layer 133 A voltage is formed between the porous electrode layers 133.

Furthermore, the control element 120 can provide a control signal to the first porous electrode layer 131 and the second porous electrode layer 133 according to the data obtained from the sensing module 110, and the control element 120 can also adjust the control signal according to the aforementioned data. .

FIG. 2 is a schematic cross-sectional view of the humidity adjustment module 130 in this embodiment. For example, referring to Figure 2, the control element 120 provides control signals to the first porous electrode layer 131 and the second porous electrode layer 133, so that the first porous electrode layer 131 and the second porous electrode layer 133 are A voltage is formed between. The humidity control layer 132 may include a porous film, and when there is liquid in the pores of the porous film, the voltage formed by the first porous electrode layer 131 and the second porous electrode layer 133 can cause the porous film to generate, for example, electro-osmosis (electro-osmosis). osmosis and other electrokinetic phenomena. Therefore, the transfer of liquid in the humidity adjustment module 130 will follow the first porous electrode layer 131 and the second porous electrode layer 133. The resulting voltage change.

Furthermore, the humidity adjustment module 130 of this embodiment has a humidity adjustment mode and a heat preservation mode. In the humidity adjustment mode, the humidity adjustment module 130 increases the moisture penetration rate. In the heat preservation mode, the humidity adjustment module 130 reduces the penetration rate of moisture. The control signal provided by the control element 120 allows the humidity adjustment module 130 to switch between the humidity adjustment mode and the heat preservation mode, and the control signal can further fine-tune the moisture penetration rate of the humidity adjustment module 130 in the humidity adjustment mode.

Referring to FIG. 1, the control element 120 and the humidity adjustment module 130 may be electrically connected in a wireless or wired manner, and the content of the disclosure is not limited to this. For example, the control element 120 may be an electronic processing element disposed on the humidity adjustment garment 100, or it may be a mobile phone, a tablet computer, or a smart watch, and may be wirelessly transmitted through Bluetooth or other wireless transmission methods or a universal serial bus (universal serial bus). Bus, USB) and other wired transmission methods are connected to the humidity adjustment module 130, and the present invention is not limited to this.

Figure 3 is a three-dimensional schematic diagram of the humidity-adjusting apparel 100 in this embodiment, in which the elements located inside the humidity-adjusting apparel 100 are drawn with dashed lines, and in Figure 3, in order to clearly show the relative positions of the elements, the elements in the humidity-adjusting apparel are omitted. Electrical connection line. On the other hand, the clothing shown in Fig. 3 is only used as a further aid in explaining the position of each element, and is not intended to limit the present invention. Nouns related to clothing parts such as hem, collar, bust, shoulder stitching, front part, back part used in this manual are intended to describe the position of each element, and are not used to limit the shape or style of the clothing. In other embodiments of the present disclosure, the position of each element may refer to the corresponding position configuration or design of the nouns related to clothing parts mentioned above. It does not exceed the scope of this disclosure to protect.

Please refer to FIG. 3, in this embodiment, the humidity adjustment apparel 100 includes a sensing module 110, a humidity adjustment module 130 and a control element 120. The sensing module 110 is disposed on the inner side of the humidity-adjusting apparel 100 and is located on the bust 101 of the humidity-adjusting apparel 100 and adjacent to the collar 102 of the humidity-adjusting apparel 100. The humidity adjustment module 130 is disposed between the hem 104 and the collar 103 of the humidity adjustment apparel 100. The control element 120 is electrically connected to the sensing module 110 and the humidity adjustment module 130.

For example, the control element 120 is connected to the sensing module 110 and the humidity adjustment module 130 via Bluetooth. The humidity adjustment apparel 100 may further include a wireless transmission module 121 which is disposed on the sleeve of the humidity adjustment apparel 100 and is electrically connected to the sensing module 110 and the humidity adjustment module 130 in a wired connection. For example, the sensing module 110 may transmit the first physiological information or the second physiological information through the wireless transmission module 121, and the humidity adjustment module 130 may receive the control signal through the wireless transmission module 121.

FIG. 4 is a schematic diagram of the sensing module 110 in this embodiment, and FIG. 4 is drawn from the perspective facing the inner side of the humidity adjustment garment 100. Please refer to FIG. 4, in this embodiment, the sensing module 110 includes a temperature sensor 112, which is disposed on the inner surface 105 of the humidity adjusting garment 100. For example, the temperature sensor 112 may be a thermopile or a charged-coupled device suitable for receiving infrared rays, which may be infrared rays emitted from the user's skin or generated from the user's skin Image measurement temperature.

On the other hand, please refer to FIGS. 3 and 4 together. In the humidity adjustment apparel 100, the sensing module 110 is disposed on the bust 101 and is adjacent to the humidity adjustment The collar 102 of the apparel 100, so the measurement area of the sensing module 110 can correspond to the chest of the user. If the user's body temperature rises due to increased activity, or the body temperature decreases due to other physiological factors, the sensing module 110 of the humidity adjustment apparel 100 can efficiently measure the user's body temperature.

Fig. 5 is a schematic cross-sectional view drawn according to the section line 5-5 in Fig. 3, in which the thickness of each layer is enlarged and drawn for the convenience of description. Please refer to FIG. 5, in this embodiment, the first porous electrode layer 131 of the humidity adjustment module 130 is adjacent to the inner side of the humidity adjustment apparel 100 (please refer to FIG. 3), that is, adjacent to the humidity adjustment apparel 100 (please refer to Fig. 3) Surface 105 facing inward. The second porous electrode layer 133 of the humidity adjustment module 130 is adjacent to the outer side of the humidity adjustment apparel 100 (please refer to FIG. 3), that is, adjacent to the outer surface 106 of the humidity adjustment apparel 100 (please refer to FIG. 3). The humidity control layer 132 is located between the first porous electrode layer 131 and the second porous electrode layer 133. Therefore, when the control element 120 (please refer to FIG. 3) provides control signals to the first porous electrode layer 131 and the second porous electrode layer 133 of the humidity adjustment module 130, the first porous electrode layer 131 and the second porous electrode layer 133 The voltage formed by the two porous electrode layers 133 causes the liquid to move along the direction d1 from the inner side of the self-humidity adjusting apparel 100 (see FIG. 3) to the outer side of the humidity adjusting apparel 100 (see FIG. 3).

Furthermore, when the humidity adjustment module 130 is in the humidity adjustment mode, the humidity adjustment module 130 increases the moisture permeability along the direction d1. When the humidity adjustment module 130 is in the heat preservation mode, the humidity adjustment module 130 reduces the penetration rate of moisture along the direction d1.

Therefore, please refer to Figs. 3 to 5 together. The humidity adjustment apparel 100 can control the humidity adjustment module 130 through the control element 120 to adjust the humidity adjustment clothes. The humidity inside the ornament 100 can also be controlled by the control element 120 to control the perspiration efficiency of the humidity adjustment module 130. With the above control method, the humidity adjustment clothing 100 can relieve the user’s feeling of stuffiness or dryness, improve the efficiency of perspiration when the user is sweating, and can reduce the humidity adjustment module 130 when the user’s body temperature is low. Moisture penetration rate to provide insulation effect.

On the other hand, in this embodiment, the humidity adjustment module 130 is adjacent to the bust 101 of the humidity adjustment apparel 100, and the position of the humidity adjustment module 130 corresponds to the user's pectoralis major muscle. Therefore, when the user is exercising, the humidity adjustment module 130 is arranged on the humidity adjustment apparel 100 at a position where it is easy to contact the user and the user may sweat. By controlling the voltage between the first porous electrode layer 131 and the second porous electrode layer 133 in the humidity adjustment module 130 by the control element 120, the user's sweat can be discharged through the humidity control layer 132 more effectively.

Figure 6 is a schematic flow chart of the method for controlling humidity adjustment apparel in this embodiment. The following components will be described with reference to the component symbols in Figure 3. Please refer to Figure 6. In this embodiment, the control method includes obtaining first physiological information from the sensing module 110 (step S11), and then determining the first physiological information Whether a physiological information meets the judgment threshold (step S12). For example, the judgment threshold can be a temperature range or a humidity range.

When the first physiological information meets the judgment threshold, the control element 120 switches the humidity adjustment module 130 from the heat preservation mode to the humidity adjustment mode (step S13). Then the control method of this embodiment obtains the second physiological information (step S14), and the control element 120 adjusts the control signal in the humidity adjustment mode according to the second physiological information (step S15). For example, the method for obtaining the second physiological information may include obtaining the second physiological information via the sensing module 110, or via The control component 120 obtains the preset and stored second physiological information, but the content of the disclosure is not limited to this.

Specifically, in this embodiment, the first physiological information includes the temperature in the humidity adjustment apparel 100. The control element 120 can also store the age of the user, and the second physiological information includes the age of the user.

For example, the judgment threshold of this embodiment is to judge whether the temperature exceeds 33 degrees Celsius. When the temperature in the humidity adjustment garment 100 is 33 degrees Celsius or lower, the humidity adjustment module 130 can be maintained in the heat preservation mode because the user is not likely to feel hot.

When the temperature in the humidity adjustment apparel 100 exceeds 33 degrees Celsius, because the user easily starts to feel hot, the humidity adjustment module 130 can switch to the humidity adjustment mode.

According to the user's age of the second physiological information, the control element 120 can adjust the control signal in the humidity adjustment mode. For example, the method of adjusting the control signal may include adjusting the period, frequency, or pulse width of the control signal, but the present invention is not limited thereto. For another example, when the user is younger than twenty years old, because users in this age range have higher body metabolism, the control signal can increase the frequency or period of the control signal according to the user's age. When the user is older than sixty-five years old, because the body resistance of users in this age range is low, the control signal can reduce the frequency or period of the control signal.

Specifically, the control signal includes, for example, a plurality of pulse signals, the aforementioned frequency is the number of pulse signals sent per second, and the aforementioned period is the time length of each pulse signal.

Furthermore, the control signal can also be adjusted by means of Pulse Width Modulation (PWM).

In the control method of this embodiment, the second physiological information may include continuous exercise time. The aforementioned continuous exercise time is the cumulative time after the first physiological information meets the judgment threshold, and the control method of this embodiment can cumulatively adjust the voltage of the control signal over time.

For example, the control method of this embodiment can gradually increase the voltage of the control signal before the continuous exercise time accumulates to 30 minutes, and control the humidity adjustment module 130 with the maximum voltage control signal after 30 minutes, thereby providing the highest efficiency Humidity adjustment function, and at the same time, it can cooperate with the user’s warm-up exercise to provide a better humidity adjustment function during the first 30 minutes of exercise.

Furthermore, the control signal in the control method of this embodiment can be determined by a mechanical training model. In detail, the above-mentioned mechanical training model can take temperature, user age, and continuous exercise time as input, and control signal cycle, frequency or PWM mode as output, so as to provide a function of automatically controlling humidity and adjusting clothing 100. The above-mentioned mechanical training model can be obtained by training with a regression equation, but the present invention is not limited to this.

In other embodiments of the present disclosure, the input of the above-mentioned mechanical training model may also include humidity, user's heart rhythm or environmental wind speed, so as to adjust the humidity adjustment module 130 corresponding to more different physiological conditions and environmental conditions. The following will further refer to the content of other embodiments for description.

Figures 7A and 7B are three-dimensional schematic diagrams of humidity-adjusting apparel according to another embodiment of the disclosure. The perspective of Figure 7A is toward the front of the humidity-adjusting apparel, and the perspective of Fig. 7B is toward the back of the humidity-adjusting apparel. surface. Please refer to FIGS. 7A and 7B. In this embodiment, the humidity adjustment apparel 200 is similar to the humidity adjustment apparel 100 described above, and includes a sensing module 210, a humidity adjustment module 230, and a control element 220. The details of the same elements are described in I won't repeat them here. The humidity adjustment apparel 200 of this embodiment is different from the humidity adjustment apparel 100 described above in that the humidity adjustment apparel 200 of this embodiment further includes a humidity adjustment module 234 adjacent to the garment hem 204.

In other words, the humidity adjustment apparel 100 includes a humidity adjustment module 230 located on the bust 201 of the front part 207 and also includes a humidity adjustment module 230 located on the back part 208 and adjacent to the shoulder seam 209. Meanwhile, the hem 204 of the front part 207 of the humidity-adjustable apparel 200 also includes a humidity adjustment module 234, and the hem 204 of the humidity-adjustable apparel 200 on the back part 208 also includes a humidity adjustment module 234.

Therefore, the humidity adjustment module 230 of this embodiment can provide a humidity adjustment function at the position adjacent to the user’s pectoralis major or trapezius muscle at the same time, so that the humidity adjustment garment 200 can provide effective perspiration at a position that is easily accessible to the user. Or keep warm function.

On the other hand, since the humidity adjustment apparel 200 also has these humidity adjustment modules 234 at a position adjacent to the garment hem 204, the user's sweat accumulated on the humidity adjustment apparel 200 can also be discharged through these humidity adjustment modules 234.

The humidity adjustment clothing 200 of this embodiment may further include a wind speed sensor 240 which is electrically connected to the control element 220. The wind speed sensor 240 is disposed on the front part 207 of the humidity-adjusting apparel 200 and adjacent to the shoulder stitch 209 of the humidity-adjusting apparel 200. Specifically, the wind speed sensor 240 of the humidity adjustment apparel 200 may be disposed on the front yoke 2010. When the user wears a humidity adjustment suit When decorating 200, the wind speed sensor 240 can correspond to one of the two clavicles of the user.

Furthermore, in the method for controlling the humidity adjustment apparel 200 of this embodiment, the second physiological information used to adjust the control signal may include the ambient wind speed measured by the wind speed sensor 240, and then according to the surrounding environment or the movement of the user. Speed for further humidity adjustment.

The humidity adjustment apparel 200 may further include a connecting opening 250 and a connecting structure 251. The connecting opening 250 is disposed between the hem 204 and the collar 203 of the humidity adjustment garment 200, that is, corresponding to the positions of the humidity adjustment modules 230 and 234. The connection structure 251 is disposed at the inner edge of the connection opening 250, and the connection structure 251 detachably connects the humidity adjustment modules 230 and 234 to the connection opening 250.

Fig. 8 is a schematic cross-sectional view drawn according to the section line 8-8 in Fig. 7A. Referring to FIG. 8, in this embodiment, the connecting structure 251 surrounds the first porous electrode layer 231, the second porous electrode layer 233, and the humidity control layer 232 of the humidity adjustment module 230, which is disposed in the humidity adjustment module 230 and connected to the connection opening 250. For example, the connection structure 251 may be a devil felt, so the humidity adjustment module 230 can be removed from the connection opening 250, and the removed humidity adjustment clothing 200 (please refer to FIGS. 7A and 7B) can be directly immersed in water for washing. In other embodiments of the present disclosure, the connecting structure 251 may also be a zipper, and the present disclosure is not limited thereto.

Figure 9 is a schematic diagram of the sensing module in this embodiment, and Figure 9 is drawn from the perspective facing the inside of the humidity-adjusting garment. Please refer to Figure 9, in this embodiment, the sensing module 210 includes a temperature sensor 212, and also includes humidity The sensor 214 and the heart rate sensor 216, and the humidity sensor 214 and the heart rate sensor 216 are electrically connected to the control element 220 (see FIG. 7A). For example, the heart rhythm sensor 216 may include a light source 216A and a camera unit 216B, and the user's heart rhythm can be obtained by photoplethysmography (PPG).

Furthermore, in the control method of the humidity-adjusting apparel 200 (see Figure 7A) of this embodiment, the first physiological information may include the temperature and humidity in the humidity-adjusting apparel 200 (see Figure 7A), and the second physiological information The information may include the age of the user, the user's heart rhythm, or the environmental wind speed.

FIG. 10 is a schematic diagram of a sensing module in still another embodiment of the present disclosure. In this embodiment, the sensing module 210A may include a temperature and humidity sensor 215 and a heart rhythm sensor 216, and the disclosure is not limited thereto.

In summary, the humidity adjustment garment of the disclosed embodiment can sense the physiological information of the user by the sensing module, and control the humidity adjustment module by the control element, so as to adjust the humidity between the inner and outer sides of the garment. Humidity difference. The method for controlling humidity adjustment clothing of the embodiment of the present disclosure can determine whether to switch to the humidity adjustment mode according to the first physiological information, and further adjust the control signal in the humidity adjustment mode according to the second physiological information, so as to provide a good humidity adjustment function.

100‧‧‧Humidity adjustment clothing

101‧‧‧Bust

102‧‧‧Neckline

103‧‧‧Collar

104‧‧‧Clothes

110‧‧‧Sensing Module

120‧‧‧Control components

121‧‧‧Wireless Transmission Module

130‧‧‧Humidity adjustment module

5-5‧‧‧Cutting line

Claims (10)

A humidity adjustment apparel, comprising: a sensing module configured on the inner side of the humidity adjustment apparel, the sensing module including a temperature sensor; a humidity adjustment module, configured on the hem and clothing of the humidity adjustment apparel Between the collars, the humidity adjustment module includes: a first porous electrode layer adjacent to the inner side of the humidity adjustment garment; a humidity control layer; and a second porous electrode layer adjacent to the outer side of the humidity adjustment garment , The humidity control layer is located between the first porous electrode layer and the second porous electrode layer; and a control element electrically connected to the temperature sensor of the sensing module and the The first porous electrode layer and the second porous electrode layer of the humidity adjustment module, wherein the sensing module is located on the bust of the humidity adjustment apparel and adjacent to the neckline of the humidity adjustment apparel. According to the humidity adjustment apparel described in item 1 of the scope of patent application, the sensing module includes: a humidity sensor electrically connected to the control element; and a heart rhythm sensor electrically connected to the control element . Such as the humidity adjustment clothing described in item 1 of the scope of patent application, It further includes: a wind speed sensor electrically connected to the control element, wherein the position of the wind speed sensor is arranged on the front part of the humidity-adjusting garment and adjacent to the shoulder seam of the humidity-adjusting garment. The humidity-adjusting apparel described in item 1 of the scope of patent application, wherein the humidity-adjusting module is adjacent to the hem of the humidity-adjusting apparel. The humidity adjustment apparel described in item 1 of the scope of patent application, wherein the humidity adjustment module is adjacent to the bust of the humidity adjustment apparel, and the position of the humidity adjustment module corresponds to the user's pectoralis major or Trapezius. The humidity-adjusting apparel described in item 1 of the scope of the patent application further includes: a connecting opening arranged between the hem and the collar of the humidity-adjusting apparel; and a connecting structure arranged on the inner edge of the connecting opening, and The connection structure detachably connects the humidity adjustment module to the connection opening. A method for controlling humidity adjustment clothing, comprising: providing the humidity adjustment clothing according to any one of claim items 1 to 6; obtaining first physiological information from the sensing module, and when the first physiological information meets the judgment valve Value, the control element makes the humidity adjustment module self-protection The temperature mode is switched to the humidity adjustment mode; and the second physiological information is obtained, and the control element adjusts the control signal in the humidity adjustment mode according to the second physiological information, wherein in the humidity adjustment mode, the humidity adjustment The module increases the penetration rate of moisture from the inner side to the outer side of the humidity adjustment garment, and in the heat preservation mode, the humidity adjustment module reduces the penetration rate of moisture from the inner side to the outer side. The control method according to item 7 of the scope of patent application, wherein the first physiological information includes the temperature or humidity in the humidity adjustment clothing. The control method according to item 7 of the scope of patent application, wherein the second physiological information includes the user's age, the user's heart rhythm, or the environmental wind speed. The control method according to item 7 of the scope of patent application, wherein the step of adjusting the control signal of the humidity adjustment module in the humidity adjustment mode by the control element according to the second physiological information includes: controlling the control Signal period adjustment, frequency adjustment or pulse width modulation.

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