JP2025066030A - Wearable temperature control device - Google Patents

Abstract

To provide a wearable temperature-adjusting device capable of improving the sensible temperature of a person who works in a high or low temperature environment, increasing work efficiency, and preventing injuries to the human body caused by hot or cold environments.SOLUTION: In a wearable temperature-adjusting device, an attachment body has a fan fitting part and a cold/heat source fitting part. The fan fitting part is used for fitting a fan, the cold/heat source fitting part is used for fitting a cold/heat source, and the cold/heat source cools or heats an air current introduced into a heat storage area by the fan. The attachment body has a chamber structure that spontaneously forms a chamber air duct, and includes an air inlet, the heat storage area formed by the chamber after the cold/heat source is attached, a pressure-resistant air duct, and at least one air outlet. The pressure-resistant air duct is disposed in at least a part of the chamber segments of the chamber air duct. When the chamber air duct is pressed, the pressure-resistant air duct ensures penetration of the chamber segment in which it is located.SELECTED DRAWING: Figure 1

Description

The present invention relates to packaging or clothing worn on the human body, and in particular to a wearable temperature control device.

In recent years, as the number of extreme weather events continues to increase, the demand for wearable air and temperature regulation devices (such as cooling wear) is growing. In particular, people who work or work in extremely hot conditions, as well as outdoor sports enthusiasts and those who go out in the summer, have long anticipated wearable cooling products that are relatively inexpensive, lightweight, effective, and have a wide range of applications.

Conventional wearable air and temperature control devices mainly include air-conditioned clothing equipped with a fan, water-cooled backpacks (vests) that cool by circulating cooling water, and vests (or backpacks) that cool by an electronic method using a Peltier element. At present, most wearable air and temperature control devices are generally expensive and have poor actual usage effects, for example, the efficiency of the cooling and heating effect is relatively low, the usage time is short, the preparation work before and after use is complicated, or the usage scenes are limited, etc., and they cannot provide users with a sufficient sense of temperature control and cannot meet the above general needs of users.

The working principle of air-conditioned clothing equipped with a fan is limited to evaporating sweat and achieving a cooling effect through the ventilation of a large volume of air, and it has the following drawbacks: 1. Sweating itself drains the user's physical strength, and the hot air felt when the temperature exceeds 35 degrees Celsius is uncomfortable and increases the user's irritation; 2. The use of a large volume of air from the fan creates a lot of noise; 3. The air blowing causes the clothing to expand, affecting the appearance and interfering with movement to some extent; 4. It cannot be used in conjunction with a fall prevention belt, and when carrying luggage or sitting in a chair with a backrest (for example, the seat of a work vehicle such as a crane, forklift, bulldozer, or tractor), the air duct is blocked, which has a significant impact on the results of use, and it cannot be used with the user's everyday clothes, etc.

Conventional wearable temperature control devices also use a method of circulating cooling water to lower the temperature (e.g., water-cooled backpacks and vests), but they also have the following drawbacks: 1. The usage time is short, and if there is no refrigerant, it becomes completely unusable; 2. The contact area of the cooling tube is small and the cooling area is concentrated, resulting in a large temperature difference between different parts of the body; 3. Condensation is likely to occur, causing strong physical discomfort.

The disadvantages of electronic temperature-lowering vests (or backpacks) using Peltier elements are: 1. They are expensive; 2. They have a short operating time and require large-capacity rechargeable batteries to continue functioning; 3. The area is too small to provide sufficient temperature regulation effect.

Overall, while there have been some notable advances in the field of wearable air and temperature regulating garments, challenges remain. Future development opportunities include improved designs for lower cost, a wider range of applications, and better usage outcomes.

In view of the above, embodiments of the present invention provide a wearable temperature control device that overcomes or ameliorates one or more of the shortcomings present in the prior art.

The technical solution of the present invention is as follows:

A wearable temperature control device, comprising a wearing body, the wearing body having a fan mounting section for mounting a fan and a cold heat source mounting section for mounting a cold heat source for cooling or heating the airflow introduced into the heat storage area by the fan, the wearing body having a chamber structure that spontaneously forms a chamber air duct, the chamber structure having an intake port, the heat storage area formed in the chamber after the cold heat source is installed, and at least one outlet port, air is introduced into the chamber air duct from the intake port by the fan, and is cooled or heated after passing through the cold heat source to form a temperature-adjusted airflow, the temperature-adjusted airflow is guided to the outlet port by the chamber air duct and acts on the wearer, the chamber air duct further comprising a pressure-resistant air duct, the pressure-resistant air duct is installed in at least a part of the chamber segment of the chamber air duct, and when the chamber air duct is pressed, the pressure-resistant air duct ensures the penetration of the chamber segment in which it is located.

In some embodiments, the chamber air duct and the pressure-resistant air duct communicate from the intake port through the heat storage area to the exhaust port, and the exhaust port is positioned toward the temperature adjustment area of the wearer.

In some embodiments, the fan mounting portion is located at the air inlet or at a predetermined distance from the air inlet within the chamber air duct.

In some embodiments, the air outlets include a first set of air outlets and a second set of air outlets, the temperature control area includes a first temperature control area and a second temperature control area, the first set of air outlets is arranged toward the first temperature control area of the wearer, the second set of air outlets is arranged toward the second temperature control area of the wearer, and the first set of air outlets and the second set of air outlets realize temperature transfer by thermal convection.

In some embodiments, the first temperature regulation area is the wearer's head and neck, and the second temperature regulation area is the wearer's underarms.

In some embodiments, a temperature sensing area is formed in the wearing body, and the temperature sensing area is in contact with the third temperature control area of the wearer, and the wearing body realizes temperature transfer with the third temperature control area of the wearer through a temperature transfer method.

In some embodiments, the third temperature regulation area is at least one of the wearer's shoulders, back, and waist.

In some embodiments, a support is provided within the chamber structure, the support having a certain height and positioned adjacent to the pressure-resistant air duct to support the pressure-resistant air duct.

In some embodiments, the support is a porous support structure that communicates with the heat storage area or chamber air duct through internal vents to allow temperature regulating gas that has passed through a cold source to be uniformly diffused within the porous structure of the support and conducted to the temperature sensing area.

In some embodiments, the width of the support is smaller than the width of the corresponding portion of the mounting body, and there is a gap between the side wall of the support and the inner wall of the chamber on the corresponding side of the mounting body, the gap forming at least a portion of the pressure-resistant air duct.

In some embodiments, the support is provided in a plurality of pieces, with a gap between two adjacent supports, the gap forming at least a portion of the pressure-resistant air duct.

In some embodiments, the pressure-resistant air duct may further include an air tube installed within the mounting body.

In some embodiments, a support is placed within the chamber structure, the support has a certain height, and fills the chamber air duct, and has a gap within the support, so that the support spontaneously forms the pressure-resistant air duct.

In some embodiments, the mounting body includes a bottom composite layer and a top composite layer, the bottom composite layer being the side of the mounting body that faces the wearer and the top composite layer being the side of the mounting body that faces away from the wearer, and the bottom composite layer and the top composite layer are connected to form a chamber.

In some embodiments, in a cross-section of the mounting body, the width of the bottom composite layer is less than the width of the top composite layer, and the top composite layer bulges on either side or away from the bottom composite layer to form at least a portion of the chamber air duct.

In some embodiments, the mounting body has a support member installed at least at the position of the air outlet, which supports the air outlet, keeps the air outlet open at all times, and maintains the required air outlet angle.

In some embodiments, the support member is a half-pipe structure or a full-pipe structure that is engaged and positioned within the mounting body, and when the half-pipe structure is a semicircular pipe shape, the arc surface of the semicircular pipe abuts against the edge of the mounting body where the air outlet is located.

In some embodiments, the air outlet of the mounting body and the corresponding position of the support member are connected by a fixing member that is installed in a locked manner.

In some embodiments, the top composite layer includes an outer surface layer, a heat retention layer, and a first sealing layer arranged in layers from the outside to the inside, the heat retention layer prevents the temperature of the cold source from escaping to the outside, and the first sealing layer prevents the temperature regulating airflow in the chamber of the mounting body from leaking.

In some embodiments, the bottom composite layer includes a ventilation layer and a second sealing layer, the second sealing layer prevents leakage of the temperature regulating airflow within the chamber of the wearing body, and the ventilation layer contacts the wearer to transfer temperature.

In some embodiments, the support includes a back support and a shoulder support, the back support is disposed at a middle position or on both sides of the back of the wearing body, the pressure-resistant air duct is located on both sides or in the center of the back support, the shoulder support is located on the side of the shoulder of the wearing body away from the neck of the wearer, and the pressure-resistant air duct and the air outlet are located on the side of the shoulder of the wearing body facing the neck of the wearer and under the armpits of the wearer.

In some embodiments, when one fan mounting portion is installed, the fan mounting portion is located at a central position on the lower portion, and when two fan mounting portions are installed, the fan mounting portions are located at symmetrical positions on either side of the lower portion.

In some embodiments, the support is secured to and positioned within the chamber of the wearer's body by a second sealing layer or breathable fabric material.

In some embodiments, the support has a second sealing layer sewn tightly to the mounting body, and the second sealing layer has a plurality of internal ventilation holes.

In some embodiments, the cold source is a cold source or a heat source, and includes at least one of a cold drink, a hot drink, an ice pack, a heating pad, and a thermoelectric device.

In some embodiments, the wearing body is one of a vest, a waistcoat, a backpack, and a waist pouch.

In the wearable temperature control device of the present invention, a cold source is placed downstream of a fan along the air flow direction of the chamber air duct, and the air introduced into the chamber from the intake port by the fan is temperature-controlled in the heat storage area where the cold source is present, and then becomes cold air that is lower than the external environment or hot air that is higher than the external environment, and is sent to one or more outlets in the air duct, and uses a thermal convection method (i.e., direct airflow) to cool or heat the first temperature control area of the wearer. A pressure-resistant air duct is installed in the wearable temperature control device, and the pressure-resistant air duct is installed in at least a part of the chamber segment of the chamber air duct, and when the chamber air duct is pressed, the pressure-resistant air duct ensures the penetration of the chamber segment in which it is located. The pressure-resistant air duct can be installed in a part that is easily pressed, for example, corresponding to a specific area such as the wearer's joints, shoulders, or the middle position of the back. The pressure-resistant air duct can be designed according to different application scenes, differences in the wearer's working style, etc.

Additional advantages, objects and features of the present invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon study of the following description, or may be learned by practice of the invention. The objectives and other advantages of the present invention may be realized or learned through the configurations particularly illustrated in the specification and claims hereof, as well as the drawings.

Those skilled in the art should understand that the objectives and advantages that can be achieved by the present invention are not limited to those specifically described above, and the above and other objectives that can be achieved by the present invention can be more clearly understood based on the detailed description below.

The drawings described herein are intended to facilitate understanding of the present invention and are part of this application, but are not intended to limit the present invention. The elements in the drawings are not drawn to scale, and are intended only to illustrate the principles of the present invention. In order to clearly illustrate and explain parts of the present invention, the corresponding parts in the drawings may be enlarged, i.e., larger than other parts of an exemplary device actually manufactured according to the present invention. The drawings are as follows:
FIG. 2 is an exploded view of the wearable temperature control device according to the first embodiment of the present invention. 1 is a schematic front view of a wearable temperature controller according to a first embodiment of the present invention; 1 is a schematic diagram showing a wearable temperature control device according to a first embodiment of the present invention, which corresponds to each temperature control area of a wearer. FIG. 2 is a structural diagram of the constituent materials of each layer of the packaging body of the wearable temperature control device in some embodiments of the present invention. 1 is a schematic diagram of a side structure of a packaging body of a wearable temperature control device in some embodiments of the present invention. 1 is a schematic cross-sectional view of a shoulder portion of a wearable temperature regulating device in some embodiments of the present invention. FIG. 2 is a structural diagram of the position of the air outlet of a wearable temperature control device in some embodiments of the present invention. FIG. 2 is an end view of the structure of the air outlet position of a wearable temperature control device in some embodiments of the present invention. FIG. 2 is a structural schematic diagram of the bottom composite layer and support of the wearable temperature regulating device in Example 1 of the present invention. 1 is a schematic diagram of a wearable temperature control device using different cooling sources in some embodiments of the present invention. FIG. 11 is a schematic diagram of the front structure of a wearable temperature regulator according to a second embodiment of the present invention. FIG. 11 is a schematic diagram of the front structure of a wearable temperature control device according to a third embodiment of the present invention. FIG. 11 is a schematic diagram of the front structure of a wearable temperature regulator according to a fourth embodiment of the present invention. FIG. 13 is a schematic diagram of the front structure of a wearable temperature control device according to a fifth embodiment of the present invention. FIG. 13 is an exploded view of a wearable temperature regulator according to a sixth embodiment of the present invention.

In order to more clearly illustrate the objectives, technical solutions and advantages of the present invention, the present invention will be described in more detail below with reference to the embodiments and drawings. Here, the outline of the present invention and its description are intended to clarify the present invention and are not intended to limit the present invention.

It should be noted here that in order to avoid obscuring the present invention with unnecessary details, the drawings show only the structures and/or process steps closely related to the solution of the present invention, and omit other details less relevant to the present invention.

Note that when the term "includes" is used in this specification, it refers to the presence of a feature, element, step or module, but does not exclude the presence or addition of one or more other features, elements, steps or modules.

It should be noted here that unless otherwise specified, the term "connection" in this specification includes not only direct connection but also indirect connection via an intermediate.

Below, an embodiment of the present invention will be described with reference to the drawings. In the drawings, the same reference numerals indicate the same or similar components or steps.

The present invention provides a wearable temperature control device, the main purpose of which is to improve the physical comfort of workers (in special tasks, outdoor work, outdoor activities, etc.), increase the efficiency of outdoor work, prevent personal injury caused by hot/cold environments, and provide comfortable microenvironments and working conditions.

In some embodiments, as shown in FIG. 1, the wearable temperature control device may include a wearing body. The wearing body is attached to the user's body by a certain self-structure or an additional attached structure, such as a connecting belt, an elastic band, a buckle and a hook, etc. The wearing body may be a carrier for mounting a fan 4, a heat and cold source, an energy storage battery, etc.

Here, as shown in Figures 1 to 5, the mounting body includes a fan mounting portion 1-4 for mounting a fan 4 and a cold heat source mounting portion 1-16 for mounting a cold heat source, and the cold heat source is for cooling or heating the airflow that the fan 4 introduces into the heat storage area or the chamber air duct 11.

The wearing body is a chamber structure that spontaneously forms a chamber air duct 11, and the chamber structure has an intake port 13, a heat storage area formed by the chamber after the cold heat source is installed, and at least one air outlet 12. It should be understood that the inside of the wearing body in the present invention is a mutually penetrating chamber structure, and all chamber structures spontaneously form a chamber air duct 11, and the illustrated range of the chamber air duct 11 in FIG. 1 is shown only as a planar area, but is not limited to this, and any connected three-dimensional area within the chamber can be called a chamber air duct 11, and corresponds to the back, shoulders, waist, etc. of the wearer, but is not limited to this, and may be within a porous support structure.

The chamber air duct 11 may further include a pressure-resistant air duct 14 installed in at least some of the chamber segments of the chamber air duct 11, and when the chamber air duct 11 is pressed, the pressure-resistant air duct 14 ensures the penetration of the chamber segment in which it is installed. Alternatively, all of the chamber air ducts 11 of the mounting body are pressure-resistant air ducts 14.

The concept of the heat storage area proposed in this invention should be understood as follows: after the airflow introduced by the fan passes through the cold source, the airflow is cooled or heated, and the cooled or heated temperature-adjusted airflow fills and circulates throughout the entire space within the chamber of the mounting body, and the supporting structure, inner surface structure, etc. are cooled or heated accordingly. The entire chamber air duct may be the heat storage area, or the entire chamber air duct and its supporting structure, inner surface structure, etc. may be the heat storage area.

The concept of the chamber air duct is as described above, and the pressure-resistant air duct 14 can be a part of the chamber air duct 11, that is, a part of the air duct of the chamber air duct 11 is a pressure-resistant air duct, where the part of the air duct can be configured in the length direction, height direction, or width direction so as to be applicable to more application scenarios, to obtain higher reliability, and not to affect the exhaust effect after the air duct is pressed. Of course, in these embodiments, it is also possible to configure all of the chamber air ducts 11 as pressure-resistant air ducts.

In the embodiment of the present invention, a pressure-resistant air duct is installed in the wearable temperature control device, and the pressure-resistant air duct 14 is installed in at least a part of the chamber segment of the chamber air duct 11, so that when the chamber air duct 11 is pressed, the pressure-resistant air duct 14 ensures the penetration of the chamber segment in which it is installed. For example, the pressure-resistant air duct 14 can be installed in a specific area corresponding to a part that is easily pressed, such as a joint, shoulder, or middle position of the back of the wearer. The pressure-resistant air duct 14 can be designed according to different application scenes, differences in the working style of the wearer, etc.

In the above embodiment, the wearable temperature control device of the present invention has a cold source installed downstream of the fan 4 along the air flow direction of the chamber air duct 11, and the air introduced into the chamber by the fan 4 from the intake port 13 is temperature-controlled in the heat storage area where the cold source is installed, and then becomes cold air that is colder than the external environment or hot air that is hotter than the external environment, and is sent to one or more outlets 12 in the chamber air duct 11 and the pressure-resistant air duct 14, where the temperature is reduced or increased in the temperature control area of the wearer by the thermal convection method (i.e., direct airflow blowing).

In some embodiments, the fan mounting position can be diversified. The fan mounting part 1-4 is located at the air inlet 13, i.e., the fan is mounted at the air inlet. Alternatively, the fan is mounted in the chamber air duct 11, and the fan mounting part 1-4 is located at a position in the chamber air duct 11 that is a certain distance from the air inlet 13, for example 1-10 cm. In this case, the utilization rate of the chamber air duct 11 decreases, but it can be ensured that the fan is less likely to be damaged or blocked by external foreign objects, resulting in noise or fan breakage.

The dimensions of the fan are selected to cover the entire chamber air duct 11 to avoid wind leakage or insufficient wind pressure. Optionally, a filter can be installed at the position of the intake port, in the chamber air duct 11, or the fan can be equipped with a filter itself, to prevent relatively large external impurities from entering the chamber air duct 11.

In some embodiments, in order to enhance the effect of using the wearable temperature control device, the wearable temperature control device of the present invention may be designed to blow air to multiple locations and multiple regions. Optionally, as shown in FIG. 2, the air outlet 12 includes a first set of air outlets 12A and a second set of air outlets 12B, and the temperature control region includes a first temperature control region and a second temperature control region. The first set of air outlets 12A is arranged toward the first temperature control region of the wearer, and the second set of air outlets 12B is arranged toward the second temperature control region of the wearer, and both the first set of air outlets 12A and the second set of air outlets 12B realize heat transfer by thermal convection (i.e., direct airflow blowing).

Optionally, as shown in FIG. 3, the first temperature control area is the head and neck area of the wearer, and the second temperature control area is the underarm area of the wearer. Both the first temperature control area and the second temperature control area are sensitive areas for temperature control, and are in accordance with the scientific heat dissipation method of ergonomics.

In the above embodiment, the first set of air outlets 12A and the second set of air outlets 12B can both be installed in a form of a combination of multiple air outlets 12. Taking into consideration the symmetrical structure of the human body, for example, when the first temperature control area corresponding to the first set of air outlets 12A is the wearer's neck, the first set of air outlets 12A includes two sets of symmetrically installed structures, and the air outlets 12 on one side of the first set of air outlets 12A are adaptively designed according to a certain interval and blowing angle to optimize the human body temperature control effect.

The above embodiment describes a first set of air outlets 12A and a second set of air outlets 12B, but it is not limited to this, and it is understood that the wearable temperature control device can be provided with a third set of air outlets 12, a fourth set of air outlets 12, a fifth set of air outlets 12, etc., which may correspond to, for example, the face, wrists or ankles, forehead or top of the head, etc. of the wearer or human body.

Take heat dissipation and cooling as an example. The neck and face are usually exposed to the external environment, so they are one of the main areas of the human body that dissipate heat. Using airflow to blow air on these areas dissipates heat quickly, which is beneficial for lowering body temperature. The wrists and ankles are pulse points in the human body, and the blood vessels are located shallowly. Blowing air on these areas helps to lower the temperature of the surrounding blood, which affects the overall body temperature. The armpits are another area that dissipates heat easily. Blowing air on the armpits promotes the evaporation of sweat, which is beneficial for lowering body temperature. The skin on the forehead and top of the head is thin, so blowing air on these areas is beneficial for lowering body temperature.

In some embodiments, as shown in FIG. 9, a temperature sensing area is formed on the wearing body, or the entire side of the wearing body facing the wearer is considered to be formed as a temperature sensing area, and the temperature sensing area comes into contact with the wearer's third temperature control area, so that the wearing body realizes temperature transfer to the wearer's third temperature control area by temperature transfer.

Furthermore, as shown in FIG. 3, the third temperature control area is at least one of the wearer's shoulders, back, and waist, and may be any combination of two, three, or more. The third temperature control area refers mainly to the area of the human body that comes into direct contact with the wearer's body, such as the back, shoulders, or waist.

The temperature sensing area (as shown in FIG. 9) is a concept for the wearer or the human body, for example, the part of the wearable body that directly contacts the human body (which may be the ventilation layer 10). When it is necessary to lower the temperature, the part has a temperature lower than the ambient temperature, so that the wearer can feel a cool sensation on contact. When it is necessary to warm up, the part has a temperature higher than the ambient temperature or body temperature, so that the wearer can feel a warm sensation on contact. The temperature sensing area may be cooled or heated by the temperature control airflow after passing through a cold source, or may store cold or hot air, or may slowly permeate the cold or hot air into the third temperature control area of the wearer. The temperature control method has the advantages of a large temperature control area, a high utilization rate of the temperature control gas, and a remarkable temperature control effect.

The temperature sensing area may include a member that is attached inside the chamber of the mounting body, for example, a thin water bag that is a sheet-like part with a certain specific heat capacity, but is not limited to this, and the temperature sensing area may include a support 9.

In some embodiments, a support 9 is disposed within the chamber structure, the support 9 having a certain height and disposed adjacent to the pressure-resistant air duct 14 to support the pressure-resistant air duct 14.

In some embodiments, the support 9 can be cooled or heated by airflow through a cold source or by storing this airflow to form a temperature sensing area, and the temperature sensing area or the stored airflow can transfer heat to the wearer's third temperature regulation area by a heat conduction method in contact with each other.

In the above embodiment, the support 9 not only supports the pressure-resistant air duct 14, but can also function as a temperature sensing area or part of the temperature sensing area.

The pressure-resistant air duct 14 in the embodiments of the present invention can be realized in various ways, for example, it can be a gap air duct formed by the support 9 and the inner wall of the chamber, or a gap air duct formed between multiple supports 9, or it can be a duct air duct buried between the support 9 and the inner wall of the chamber, or between multiple supports 9. Of course, the duct air duct has a certain supporting strength and can form the pressure-resistant air duct 14 spontaneously.

As a possible method, a support 9 is disposed within the chamber structure, the support 9 has a certain height, and is disposed adjacent to the pressure-resistant air duct 14 so as to support the pressure-resistant air duct 14. The chamber air duct 11 and the pressure-resistant air duct 14 communicate with the air outlet 12 from the fan mounting portion 1-4 through the heat storage area, and the air outlet 12 is disposed toward the first and/or second temperature adjustment area of the wearer.

In the above embodiment, the wearable temperature control device of the present invention is provided with a support 9 in a chamber structure, and the support 9 has a certain height or is designed for sufficient strength, i.e., the pressure-resistant air duct 14 is recessed low relative to the support 9, and the support 9 and the pressure-resistant air duct 14 are installed adjacent to each other to provide sufficient support for the pressure-resistant air duct 14, preventing the pressure-resistant air duct 14 from being blocked when the pressure-resistant air duct 14 is crushed, preventing air from circulating and preventing the wearer from feeling the temperature-regulating airflow.

Optionally, the support 9 is a porous support structure, and the support 9 communicates with the temperature accumulation area or the chamber air duct through the internal vents 8, so that the temperature control gas that has passed through the cold source is uniformly diffused in the porous structure of the support and conducted to the temperature sensing area. The support 9 can be a 4D air fiber or a 3D three-dimensional mesh in the prior art, and the 4D air fiber is also called a (clear) spinning ring or spinneret, and its material is TPE/TPU/PE, etc., and the inside of the fiber material is hollow, and this structure is relatively environmentally friendly, does not emit toxic and harmful substances, and further, the fibers therein have a certain self-cleaning function. The raw material of the 3D three-dimensional mesh is polyester, and it is a woven fabric that is three-dimensionally woven to form a hollow, breathable net. The support 9 can also be other structures, such as a porous flexible tube, an elastic pad made of a plurality of springs arranged in a row, or a resin frame made by combining a plurality of three-dimensional units.

In some embodiments, as shown in Figures 1, 4 and 6, the wearable body includes a bottom composite layer and a top composite layer, the bottom composite layer being the side of the wearable body facing the wearer and the top composite layer being the side of the wearable body facing away from the wearer, and the bottom composite layer and the top composite layer are connected to form a chamber. The bottom composite layer and the top composite layer may be composited using multiple layers of fabric, and the two may be connected by a stitching method, the connection being a hem 17 (as shown in Figure 6).

Optionally, as shown in FIG. 1, FIG. 6 or FIG. 9, the width of the support 9 is smaller than the width of the corresponding position of the mounting body, that is, in the width direction, the support 9 does not fill the entire chamber, but has a gap between the side wall of the support 9 and the inner wall of the chamber on the corresponding side of the mounting body, and this gap forms at least a part of the pressure-resistant air duct 14. Or, the support 9 is provided in a plurality of pieces, and there is a gap between two adjacent supports 9, and this gap forms at least a part of the pressure-resistant air duct 14. The support 9 has a certain height and elasticity, for example, the height of the support 9 is designed to be 10-50 mm, and 20 mm can be selected. The width of the pressure-resistant air duct 14 is designed to be 5-50 mm, and 15 mm can be selected. Even when the support 9 is compressed, it can ensure that the pressure-resistant air duct 14 is not completely blocked, and it can ensure that air can be normally blown even when the user carries an item on his back and the mounting body is compressed. The support 9 has a certain flexibility and lightweight design, which makes it easy for the wearer to move. The support 9 provides a certain level of comfort, is lightweight, and does not impose any extra physical strain on the wearer.

Optionally, in the cross section of the mounting body, the width of the bottom composite layer is smaller than the width of the top composite layer, so that the top composite layer rises on both sides or away from the bottom composite layer to form a chamber air duct 11, which can ensure the maximum air flow passage when there is no external pressure, and the gas introduced by the fan 4 is blown out of the outlet 12 at the maximum speed.

In addition to leaving a gap, the pressure-resistant air duct 14 in the present invention can also adopt other types, such as built-in ducts. As shown in Figures 1 and 9, the pressure-resistant air duct 14 further includes an air tube 6 arranged in the mounting body. In the embodiment of Figure 9, the mounting body has a shoulder bag structure, and there are three pressure-resistant air ducts 14 that transmit from the fan 4 to the shoulder, which are located on both sides and at the middle position of the mounting body, respectively, and both sides are gap air ducts and the middle is a duct air duct. However, this is not limited to this, and for example, one, two, or any number of ducts can be used. The pressure-resistant air duct 14 can be of any type, for example, one part is a gap air duct, another part is a duct air duct, or any part is a combination of air ducts of any type.

In some embodiments, as shown in FIG. 1, the air outlet 12 is located at least on the edge of the wearing body, but is not limited thereto, and the air outlet 12 may be located on the top or bottom surface of the wearing body. If the air outlet 12 is also provided in advance on the wearing body at the shoulder position, the airflow can be guided to the neck, face, or forehead of the wearer.

In some embodiments, as shown in Figures 6 to 9, the mounting body is provided with a support member 7 at least at the position of the air outlet 12 to support the air outlet 12, thereby keeping the air outlet 12 open at all times and maintaining the required air outlet angle.

In some embodiments, the support member 7 may be installed not only at the position of the air outlet 12, but also at all or part of the pressure-resistant air duct 14. The support member 7 may be located inside or outside the chamber of the mounting body, and supports it from the outer surface of the mounting body.

Furthermore, the support member 7 is a half-pipe structure that is engaged and installed within the mounting body. The half-pipe structure can be an arc-shaped pipe, a semicircular pipe, a semi-rectangular pipe, or the like. When the half-pipe structure is a semicircular pipe, the arc surface of the semicircular pipe abuts against the edge of the mounting body where the air outlet 12 is located, and the arc structure has a certain directional effect, and the set air outlet angle can be maintained regardless of the position of the air outlet 12.

The support member 7 may be installed integrally or in segments at the shoulder or underarm positions on both the left and right sides. As shown in FIG. 1, the support member 7 includes a first support member 7A and a second support member 7B, the first support member 7A is installed on the inside of the shoulder, has an integral structure on both the left and right sides, and supports a first set of air outlets 12A on both the left and right sides of the shoulder. The second support member 7B is installed in the underarm area, and is installed independently in two left and right segments, and supports a second set of air outlets 12B on both the left and right sides of the armpits, respectively.

To further strengthen the fixing and directing action of the air outlet, the air outlet 12 of the mounting body and the corresponding position of the support member 7 are connected by a fixing member 18 that is engaged and installed. As shown in Figures 1 and 8, the air outlet 12 of the mounting body and the semicircular pipe-shaped support member 7 are fixedly connected using the fixing member 18, the support member 7 is fixed inside the chamber air duct, and the air outlet 12 maintains a constant blowing angle throughout.

The fixing member 18 not only has a certain shaping effect, but also prevents the thread from coming loose when the mounting body is at the position of the air outlet 12. The fixing member 18 also has a positioning effect on the support member 7, preventing the support member 7 from moving around inside the chamber. Holes should be drilled at the corresponding parts of the air outlet 12, the fixing member 18 and the support member 7, and the dimensions should match and the shape should have the same structure, including but not limited to a circle, ellipse, triangle, quadrilateral, polygon or a shape combining curves.

The fixing member 18 has a certain length, and both ends are fixed to the outside of the air outlet 12 and the inside of the support member 7, respectively, and engage and fix the two. Specifically, the outer surface layer 1, the first sealing layer 3 (or the second sealing layer 5) and the support member 7 are crimped together. The fixing member 18 can be made of a material having a certain hardness, such as metal or plastic material, but is not limited to this, and soft materials such as rubber can also be used. The fixing member 18 can be an eye-catcher, a grommet, etc.

In order to achieve the desired temperature regulation effect, the volume, speed and cross-sectional area of the cold or hot air from the outlet 12 must be scientifically designed. The opening width or diameter of the outlet 12 or the fixing member 18 is 4-20 mm, and 6-10 mm can also be selected. At least one is installed on each side of the head, neck and armpits of the human body, and three or more may be installed. When the dimensions of a single outlet 12 are set small enough relative to the overall length of the chamber air duct, that is, the cross-sectional area of the outlet is made small enough, the temperature regulation airflow forms a wind flux with a constant wind speed or pressure, and a smaller volume of air can be used to provide a stronger temperature regulation stimulus to the human body, thereby achieving the purpose of improving the comfort of the human body.

Similarly, the size and quantity of the intake ports can be designed to correspond to the fan's power, air volume, air pressure, wind speed, efficiency, input voltage, external dimensions, installation method, etc.

In the above embodiment, the support member 7 can be made of a soft tube material structure, such as a PVC corrugated tube, to have a certain degree of flexibility and elasticity. The support member 7 is also part of the air duct system, and can be combined with a support using a mesh material to provide an air duct system that is both supportive and flexible.

The wearable temperature control device of the present invention uses a mesh material support and a soft tube material support, and is combined with a specific sewing method to combine the air duct. The specific material and manufacturing method allow the wind direction of the outlet to be controlled, achieving the optimal cooling effect. The mesh material and exhaust hole design allow the cold air to be exhausted in the most important areas (neck and armpits) and the second most important area (back), achieving the optimal physical sensation while increasing the effective use of the cold source.

In some embodiments, as shown in Figs. 1 and 4, the top composite layer includes an outer surface layer 1, a heat retaining layer 2, and a first sealing layer 3, which are arranged in layers from the outside to the inside. An air inlet 13 is provided on the top composite layer, and a fan can be attached at the position of the air inlet 13.

Optionally, the outer surface layer 1 can be made of some abrasion-resistant fabric, such as sports-type Oxford fabric, which has very high abrasion resistance and durability.

Optionally, the thermal insulation layer 2 can be made of a fabric material with good thermal insulation performance, such as EVA foam or cotton pearl, to prevent the temperature of the cold/heat source from leaking out. The first sealing layer 3 can be made of a fabric material with good airtightness, such as a coated fabric. When cooling is required, the coating layer can be made of light-reflective silver, which has a sealing effect and can also reflect ultraviolet rays, reducing the absorption of heat from the external environment. The TPU silver film reflective fabric can not only prevent gas leakage, but also refract the temperature of the cold/heat source. The thermal insulation layer 2 prevents the temperature of the cold/heat source from leaking out, and the first sealing layer 3 prevents the airflow in the chamber of the mounting body from leaking out.

The thermal insulation layer 2 and the first sealing layer 3 of the embodiment of the present invention can maximize the temperature-regulating airflow and cold/heat quantity stored within the chamber or package, minimize the heat exchange between the temperature inside the chamber and the external environment (the side not in contact with the human body), and minimize the leakage of the temperature-regulating airflow from the top composite layer, maximizing the utilization rate of the cold source and ensuring maximum temperature-regulating ability.

Optionally, the bottom composite layer includes a ventilation layer 10 and a second sealing layer 5, the second sealing layer 5 prevents the airflow in the chamber of the wearing body from leaking, and the ventilation layer 10 contacts the wearer to transfer temperature. In some embodiments, the support 9 is located between the ventilation layer 10 and the second sealing layer 5 to form a temperature sensing area. In order to increase the heat transfer efficiency from the wearing body to the third temperature regulation area of the human body, the second sealing layer 5 can also adopt a corresponding ventilation material. The ventilation layer 10 can be made of a ventilation mesh fabric, which is the side that contacts the human body and serves as an outer packaging body to protect the internal structure of the wearing body, but can also conduct the cold or hot air in the temperature sensing area, or transfer the temperature to the third temperature regulation area of the human body by contact. The ventilation mesh fabric also has the effect of improving comfort and breathability. This structural design is also less likely to condense, improving the comfort of the body.

In some embodiments, most of the chamber air duct 11 may be surrounded by the first sealing layer 3 and the second sealing layer 5 to minimize air leakage. The surfaces of the first sealing layer 3 and the second sealing layer 5 have a smooth coating layer to minimize wind pressure loss. Except for the position of the inlet, there is no part of the entire chamber air duct 11 surrounded by the first sealing layer 3 and the second sealing layer 5, and it is a thermal convection outlet through which the airflow of the first temperature control area, the second temperature control area, etc. blows directly, or the heat storage area/chamber air duct 11 is a vent that flows into the temperature sensing area/ventilation layer 10, and the temperature sensing area/ventilation layer 10 realizes temperature transfer with the wearer's third temperature control area through a temperature transfer method. The above two types of heat exchange methods, heat convection and heat exchange, and the two types of heat exchange structures, the air outlet and the two types of temperature sensing areas/ventilation layer 10, maximize the limited amount of cold/heat from the cold source and the limited temperature regulating airflow, acting on the wearer's sensitive temperature regulating areas and maximizing the utilization rate of the cold source.

In some embodiments, the mounting body is a structure of any one of the following types: a vest, a waistcoat, a backpack, and a waist pouch.

Next, taking the cooling effect as an example, in Example 1 shown in FIG. 2 and Example 4 shown in FIG. 13, the wearing body is a vest type, and the wearing method is the same as that of a conventional vest. Here, the wearing body of Example 1 shown in FIG. 2 has two sets of air outlets 12, namely, a first set of air outlets 12A located at the neck and a second set of air outlets 12B located under the armpits. The wearing body of Example 4 shown in FIG. 13 may have only one set of air outlets 12, namely, the air outlets 12 located under the armpits. In another embodiment, the wearing body may have only one set of air outlets 12 located at the neck.

The attachment body in Example 2 shown in FIG. 11 and Example 3 shown in FIG. 12 is a vest bag type, and the wearing method is similar to a conventional vest bag or backpack. Note that the attachment body in Example 2 shown in FIG. 11 is a single fan type, and the attachment body in Example 3 shown in FIG. 12 is a double fan type.

The fan mounting part 1-4 can be located at the bottom, middle or top of the mounting body, and there is no particular restriction on the installation position, as long as it is capable of sucking in air and is located upstream of the cold heat source. The installation position of the fan mounting part 1-4 is related to the length of the pressure-resistant air duct 14 and the spare length for attaching the cold heat source. In general, the more cold heat sources are installed, the farther the fan 4 needs to be from the air outlet 12. As shown in FIG. 11, when one fan mounting part 1-4 is installed, the fan mounting part 1-4 is located in the center of the bottom.

In the double-fan type mounting body of Example 3 shown in FIG. 12, the fan mounting parts 1-4 are located at symmetrical positions on both sides of the lower part, and a first fan 4A and a second fan 4B are mounted on each of them, but this is not limited to this and they may be installed asymmetrically.

Classified according to the number of fans, the single-fan type mounting body is applied to scenes such as electrical work with a toolbox attached to the side, and the double-fan type mounting body is applied to scenes where the driver sits on the seat and drives construction machinery such as cranes, forklifts, bulldozers, tractors and excavators. Since the fans 4 are installed on both sides, the seat back does not block the intake, and the wearable temperature control device can normally intake air to cool or warm. Naturally, the double-fan type mounting body is used in more application scenes, and when the fan 4 on one side is sealed, the fan 4 on the other side can normally intake air to work, and has higher applicability and allowable error rate. It should be understood that the more fans 4 installed in the mounting body, the greater the intake volume per unit time, and accordingly, the better the cooling or warming effect, but the power consumption will increase and the endurance time will be shorter. In specific use, an appropriate type of mounting body can be selected according to the industry occupation, application scene, etc.

As shown in FIG. 14, the attachment body of Example 5 is a waist pouch type, and its wearing method is similar to that of a conventional waist pouch. A connection belt 19 and a buckle, etc. can be arranged on the shoulder and/or waist of the attachment method, and the fastening method of a conventional waist pouch can be referred to. There is a fastener tape on the back of the attachment body, and its function is to connect or separate both sides of the fastener 15 to each other, making it easy to open and close, and allowing the cold/heat source, storage battery, fan 4, etc. to be attached and detached.

The fan mounting portion 1-4, the cold/hot source mounting portion 1-6, and the battery mounting portion (not shown) may be a bag structure sewn into the chamber or packaging of the mounting body, or may have a fixing structure such as a buckle. The chamber or packaging of the mounting body may be opened using a fastener or a magnetic buckle to facilitate replacement of the fan, cold/hot source, energy storage battery, etc. The mounting body in Example 6 shown in Figure 15 is a vest type. In Example 6, a support 9 is disposed in the chamber structure, the support 9 has a certain height, fills the chamber air duct 11, and has a gap in the support 9, so that the support 9 can spontaneously form a pressure-resistant air duct. In this embodiment, the support 9 can be made of materials such as 3D or 4D three-dimensional mesh pads, and no direct current passage is installed, and the airflow inside the support 9 is turbulent, so the wind resistance is relatively large and the airflow at the air outlet is relatively small, but the temperature control airflow in the temperature sensing area such as the back is relatively large, and the temperature control ability of the third temperature control area is enhanced, which is applicable to some specific application scenarios.

As shown in FIG. 9, the support 9 includes a back support 9 and a shoulder support 9, and a gap is formed between the back support 9 and the shoulder support 9 as a pressure-resistant air duct 14. The back support 9 is disposed at a middle position of the back of the wearing body, and the pressure-resistant air duct 14 is located on both sides of the back support 9. The shoulder support 9 is located on one side of the shoulder of the wearing body (the side away from the neck), and the pressure-resistant air duct 14 and the air outlet 12 are located on the side of the shoulder of the wearing body facing the neck of the wearer.

To fix the support 9, in some embodiments, the support 9 is fixedly positioned in the chamber of the mounting body by a positioning structure. Furthermore, as shown in Figs. 9 and 6, in some embodiments, the support 9 is wrapped in a second sealing layer 5 and sewn to the mounting body, and the second sealing layer 5 has several ventilation holes 8.

As shown in FIG. 1, the support 9 may include a first support 9A located at the mid-back, a second support 9B located at the upper shoulder, and a third support 9C located at the lower back. The internal vents 8 may include a first vent 8A, a second vent 8B, and a third vent 8C. The first support 9A at the mid-back can communicate with the chamber air duct 11 through the first vent 8A, the second support 9B at the upper shoulder can communicate with the chamber air duct 11 through the second vent 8B, and the third support 9C at the lower back can communicate with the chamber air duct 11 through the third vent 8C.

The second ventilation hole 8B shown in FIG. 1 is an internal ventilation hole that discharges the cold/hot gas in the cold/hot storage area to the temperature sensing area. The second ventilation hole 8B can be located not only on the side wall of the support 9, but also on the end surface facing the top composite layer, or on the edge boundary between the top end and the side wall. The number of the second ventilation holes 8B, the size and spacing of the openings can be set according to the actual situation or different types, or the material of the second sealing layer itself can be replaced with a breathable cloth material.

In some embodiments, as shown in FIG. 1, the support 9 can further include a double-sided support, which is located on the straps on both sides and is also closely sewn to the mounting body by a second sealing layer 5, and a third ventilation hole 8C is opened in the sealing layer to facilitate the cold or hot air in the pressure-resistant air duct 14 to enter the temperature sensing area.

In some embodiments, the cold source can also take multiple forms. The cold source here means a cold source or a heat source. When a human body needs to be cooled in a hot environment, a cold source needs to be used, and when a human body needs to be warmed in a cold environment, a heat source needs to be used. The cold source includes at least one of a cold drink, a hot drink, an ice pack, a heating pad, and a thermoelectric effect device. The thermoelectric effect device can be selected from a diode, a cooling/heating semiconductor, etc.

As shown in FIG. 10, the cold/hot drink 16A in FIG. 10(a) is a common bottled liquid such as mineral water, beverages, etc., and its manufacturing process is simple and convenient, and the use and replacement costs of the cold and heat source are low, which is favorable for large-scale popularization. The air cooling/heating pad 16B in FIG. 10(b) can be obtained using an industrial pre-fabrication method, and has good cooling or heating effect and long endurance. The diode cooling/heating semiconductor Peltier element 16C in FIG. 10(c) is a semiconductor device that uses the thermoelectric effect to perform cooling and heating. This technology is based on the thermoelectric effect discovered by Peltier (Jean Charles Athanase Peltier), in which the flow of electric current induces the transfer of heat in the semiconductor material, making one side hot and the other side cold. The metal cold/heat conducting surface 16C-1 is installed inside the heat storage chamber, and the heat dissipation structure 16C-2 is installed outside the heat storage chamber. Multiple diode cooling/heating semiconductors can be installed in the heat storage area to enhance the temperature control effect.

In some embodiments, a battery attachment section can be provided on the mounting body to attach an energy storage battery that supplies power to the fan, and a general charger or the like can be used as the energy storage battery to reduce operating costs.

The wearable temperature control device of the present invention uses a small amount of simple cold source (such as a bottled frozen drink or an ice pack) to cool important parts of the human body (such as the neck, armpits, back, etc.) with minimal energy consumption (such as a commercially available mobile battery), thereby improving the effectiveness and usage time of the product and reducing the burden on the user.

The wearable temperature control device of the present invention not only regulates temperature, but also humidity.

While conventional technologies are unable to effectively handle the load on the back, the wearable temperature control device of the present invention has a structure that forms an air duct inside the product, and the effective support provided by the air duct allows air to pass through normally even when the product is carrying a heavy object (seat belt, lawn mower, backpack, etc.), thereby ensuring that the product functions effectively.

The wearable temperature control device of the present invention can also be equipped with a smart control system and can be connected to a smartphone application, allowing users to adjust the temperature and ventilation of the garment via their mobile phone. This product can be used in a variety of application fields, including outdoor sports, industrial work, healthcare, and users with special needs (elderly and disabled).

The main body of the wearable temperature control device of the present invention is made of conventional, common and relatively mature materials, which are low cost and easy to maintain, and have cost advantages and stability compared to conventional popular wearable air and temperature control devices.

The wearing body structure of the wearable temperature control device of the present invention is easy and comfortable enough to be worn without affecting human work operations, especially on hot days or when high activity is required, and its temperature control function greatly improves the comfort of the human body. By using the wearable temperature control device manufactured according to the present invention, the user's perceived temperature can be reduced, improving the perceived comfort of people in high-temperature environments, improving work efficiency, and preventing injury to the human body caused by extremely hot environments.

In the present invention, features described and/or illustrated with respect to one embodiment may be used in the same or similar manner in one or more other embodiments and/or may be combined with or substituted for features of the other embodiments.

The above is merely a preferred embodiment of the present invention, and is not intended to limit the present invention. Various modifications and variations can be made to the embodiments of the present invention by those skilled in the art. All modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention also belong to the scope of the present invention.

1 Outer surface layer 2 Thermal insulation layer 3 First sealed layer 1-4 Fan mounting portion 1-16 Cold heat source mounting portion 4 Fan 4A First fan 4B Second fan 5 Second sealed layer 6 Air tube 7 Support member 7A First support member 7B Second support member 8 Vent 8A First vent 8B Second vent 8C Third vent;
9 Support 9A First support 9B Second support 9C Third support 10 Ventilation layer 11 Chamber air duct 12 Outlet 12A First set of outlets 12B Second set of outlets 13 Inlet 13A First inlet 13B Second inlet;
14 Pressure-resistant air duct 15 Fastener;
16A cold drink/hot drink 16B refrigerant/heating pad 16C diode cooling/heating semiconductor 17 trim 18 fixing member 19 connecting belt

Claims (27)

A wearable temperature control device,
The wearable temperature control device includes a wearing body,
The mounting body includes:
a fan mounting portion (1-4) for mounting a fan (4);
a cold heat source mounting portion (1-16) for mounting a cold heat source that performs cooling or heating on the airflow introduced into the heat storage area by the fan (4);
The wearing body is a chamber structure that spontaneously forms a chamber air duct (11), and has an inlet (13), the heat storage area formed in the chamber after a cold heat source is installed, and at least one outlet (12), and air is introduced from the inlet (13) to the chamber air duct (11) by the fan, and is cooled or heated after passing through the cold heat source to form a temperature-adjusted airflow, and the temperature-adjusted airflow is guided to the outlet (12) by the chamber air duct to act on the wearer,
The wearable temperature control device is characterized in that the chamber air duct (11) further includes a pressure-resistant air duct (14), the pressure-resistant air duct (14) is installed in at least a portion of the chamber segment of the chamber air duct (11), and when the chamber air duct (11) is pressed, the pressure-resistant air duct (14) ensures penetration of the chamber segment in which it is located. The wearable temperature control device according to claim 1, characterized in that the chamber air duct (11) is connected from the intake port (13) through the heat storage area to the exhaust port (12), and the exhaust port (12) is arranged toward the temperature control area of the wearer. The wearable temperature control device according to claim 2, characterized in that the fan mounting portion (1-4) is located at the air inlet (13) or at a position within the chamber air duct (11) at a predetermined distance from the air inlet (13). The wearable temperature control device according to claim 2, characterized in that the air outlets (12) include a first set of air outlets (12A) and a second set of air outlets (12B), the temperature control area includes a first temperature control area and a second temperature control area, the first set of air outlets (12A) are arranged toward the first temperature control area of the wearer, the second set of air outlets (12B) are arranged toward the second temperature control area of the wearer, and the first set of air outlets (12A) and the second set of air outlets (12B) realize temperature transfer by a thermal convection method. The wearable temperature control device according to claim 4, characterized in that the first temperature control area is the head and neck area of the wearer, and the second temperature control area is the underarm area of the wearer. The wearable temperature control device according to claim 1, characterized in that a temperature sensing area (10) is formed within the wearing body, the temperature sensing area is in contact with the third temperature control area of the wearer, and the wearing body realizes temperature transfer with the third temperature control area of the wearer through a temperature transfer method. The wearable temperature control device according to claim 6, characterized in that the third temperature control area is at least one of the wearer's shoulders, back, and waist. A support (9) is placed in the chamber structure,
The wearable temperature control device according to claim 1, characterized in that the support (9) has a certain height and is arranged adjacent to the pressure-resistant air duct (14) to support the pressure-resistant air duct (14). The wearable temperature control device according to claim 8, characterized in that the support (9) is a porous support structure, and the support (9) is connected to the heat storage area or the chamber air duct by internal air vents (8), so that the temperature control gas that has passed through the cold source is uniformly diffused within the porous structure of the support and conducted to the temperature sensing area (10). The wearable temperature control device according to claim 8, characterized in that the width of the support (9) is smaller than the width of the corresponding position of the mounting body, there is a gap between the side wall of the support (9) and the inner wall of the chamber on the corresponding side of the mounting body, and the gap forms at least a part of the pressure-resistant air duct (14). The wearable temperature control device according to claim 8, characterized in that a plurality of the supports (9) are provided, there is a gap between two adjacent supports (9), and the gap forms at least a part of the pressure-resistant air duct (14). The wearable temperature control device according to any one of claims 8 to 11, characterized in that the pressure-resistant air duct (14) further includes an air tube (6) installed within the wearing body. A support (9) is placed in the chamber structure,
The wearable temperature control device of claim 1, characterized in that the support (9) has a certain height and fills the chamber air duct (11) while having a gap within the support (9), such that the support (9) spontaneously forms the pressure-resistant air duct. The wearable temperature control device of claim 1, characterized in that the wearing body includes a bottom composite layer that is the side of the wearing body that faces the wearer and a top composite layer that is the side of the wearing body that faces away from the wearer, and the bottom composite layer and the top composite layer are connected to form a chamber. The wearable temperature control device of claim 14, characterized in that in a cross section of the wearing body, the width of the bottom composite layer is smaller than the width of the top composite layer, and the top composite layer bulges on both sides or in a direction away from the bottom composite layer to form at least a portion of the chamber air duct (11). The wearable temperature control device according to claim 1, characterized in that the mounting body has a support member (7) installed at least at the position of the air outlet (12), supports the air outlet (12), keeps the air outlet (12) open at all times, and maintains the required air outlet angle. The support member (7) is a half-pipe structure or a full-pipe structure that is engaged and disposed within the mounting body,
The wearable temperature control device according to claim 16, characterized in that when the half-pipe structure is in the shape of a semicircular pipe, the arc surface of the semicircular pipe abuts against the edge of the wearing body where the air outlet (12) is located. The wearable temperature control device according to claim 16, characterized in that the corresponding positions of the air outlet (12) of the mounting body and the support member (7) are connected by a fixing member (18) that is installed in an engaged manner. The wearable temperature control device according to claim 1 or 18, characterized in that the opening width or diameter of the air outlet (12) or the fixing member (18) is 4 mm to 20 mm. The wearable temperature control device according to claim 14, characterized in that the top composite layer includes an outer surface layer (1), a heat retaining layer (2), and a first sealing layer (3) arranged in layers from the outside to the inside, the heat retaining layer (2) prevents the temperature of the cold source from leaking out, and the first sealing layer (3) prevents the temperature control airflow in the chamber of the wearing body from leaking out. The wearable temperature regulation device of claim 14, characterized in that the bottom composite layer includes a ventilation layer (10) and a second sealing layer (5), the second sealing layer (5) prevents the temperature regulation airflow in the chamber of the wearing body from escaping, and the ventilation layer (10) contacts the wearer to transmit the temperature. The support (9) includes a back support and a shoulder support,
The back support is disposed at the middle position or on both sides of the back of the mounting body, and the pressure-resistant air duct (14) is located on both sides or in the center of the back support;
The wearable temperature control device of claim 8, characterized in that the shoulder support is located on the side of the shoulder of the wearing body away from the wearer's neck, and the pressure-resistant air duct (14) and the air outlet (12) are located on the side of the shoulder of the wearing body facing the wearer's neck and under the wearer's armpits. The wearable temperature control device according to claim 1, characterized in that when one fan mounting part (1-4) is installed, the fan mounting part (1-4) is located at a middle position on the lower part, and when two fan mounting parts (1-4) are installed, the fan mounting parts (1-4) are located at symmetrical positions on both sides of the lower part. The wearable temperature control device according to claim 8 or 9, characterized in that the support (9) is fixed and installed in the chamber of the wearing body on the side closest to the wearer's body by a second sealing layer (5) or a breathable fabric material. The wearable thermoregulation device according to claim 24, characterized in that the support (9) has a second sealing layer (5) sewn tightly to the wearing body, and the second sealing layer has several internal ventilation holes (8). The wearable temperature control device of claim 1, characterized in that the cold source is a cold source or a heat source, and includes at least one of a cold drink, a hot drink, an ice pack, a heating pad, and a thermoelectric effect device. The wearable temperature control device according to claim 1, characterized in that the wearing body is one of a vest, a waistcoat, a backpack, and a waist pouch.