CN112971236A - Temperature-regulating clothes and temperature-regulating equipment - Google Patents

Abstract

The invention relates to a temperature-regulating garment and temperature-regulating equipment, which comprise a liquid inlet, a liquid outlet and a plurality of temperature-regulating modules, wherein each temperature-regulating module is provided with a plurality of channels, and the temperature-regulating modules are sequentially connected so as to communicate the channels in the temperature-regulating modules; the liquid inlet and the liquid outlet are arranged on the same temperature adjusting module and communicated with the channel, or the liquid inlet and the liquid outlet are respectively arranged on two temperature adjusting modules and communicated with the channel. The temperature-adjusting clothes can achieve the functions of heat preservation or cold preservation, and temperature adjustment is not needed to be carried out by adding clothes or reducing the clothes, so that the comfort, the working efficiency and the life quality of a user are improved. Moreover, the temperature-adjusting clothes comprise a plurality of temperature-adjusting modules, and the use is convenient.

Description

Temperature-regulating clothes and temperature-regulating equipment

Technical Field

The invention relates to the technical field of temperature regulation, in particular to a temperature regulation garment and temperature regulation equipment.

Background

Under high temperature environment or low temperature environment, the operating environment of too high temperature and too low temperature has seriously influenced special trades such as traffic police, steelmaking worker, sanitation worker, among the operating workers under the airtight space such as welder, pipeline operation worker, miner, and general physical worker, long-time outdoor hiking enthusiast, the business sales force who needs long-time city to shuttle, and have special health to look after patient, old person's travelling comfort, work efficiency and quality of life, it is more loaded down with trivial details, inefficiency to carry out the temperature regulation of oneself only through increasing clothing or reducing clothing, and the effect is limited still inconvenient to carry.

Disclosure of Invention

In view of the above, it is desirable to provide a temperature control garment and a temperature control device.

A temperature adjusting garment comprises a liquid inlet, a liquid outlet and a plurality of temperature adjusting modules, wherein each temperature adjusting module is provided with a plurality of channels, and the temperature adjusting modules are sequentially connected to enable the channels in the temperature adjusting modules to be communicated; the liquid inlet and the liquid outlet are arranged on the same temperature adjusting module and communicated with the channel, or the liquid inlet and the liquid outlet are respectively arranged on two temperature adjusting modules and communicated with the channel.

Above-mentioned thermoregulation clothes can pass through the liquid of inlet input default temperature through setting up a plurality of passageways to flow into in each passageway, thereby can reach the effect of heat preservation or cold insulation, needn't carry out temperature regulation through increasing the clothing or reducing the clothing, thereby improve user's travelling comfort, work efficiency and quality of life. Moreover, the temperature-adjusting clothes comprise a plurality of temperature-adjusting modules, different temperature-adjusting modules can be used according to the requirements of users, for example, the temperature-adjusting modules can be designed into sheet modules positioned at the positions of a chest, a back and the like, can also be designed into shapes of sleeves, necklines and the like, and can also be designed into a vest shape, and each temperature-adjusting module can be directly and respectively attached to different parts of a human body or different parts of clothes through a binding band, a button, a zipper, sticky materials and the like, so that the use is convenient.

In one embodiment, the temperature-adjusting clothes further comprise a liquid temperature adjusting device, and the liquid temperature adjusting device is used for adjusting the temperature of liquid; the liquid inlet and the liquid outlet are both connected with the liquid temperature adjusting device; the liquid temperature adjusting device inputs liquid with preset temperature to the liquid inlet and flows into the channels, and the liquid flows out from the liquid outlet to the liquid temperature adjusting device.

In one embodiment, in at least one of the tempering modules, the channels comprise a parallel single-mode channel module, the parallel single-mode channel module comprises two main channel channels and a plurality of branch channel channels, and each branch channel is connected in parallel between the two main channel channels.

In one embodiment, in at least one of the temperature adjusting modules, the channel comprises a parallel multimode channel module, the parallel multimode channel module comprises at least two parallel single-mode channel modules, and the parallel single-mode channel modules are communicated with each other; the parallel single-mode channel module comprises two main channel channels and a plurality of branch channel channels, and each branch channel is connected between the two main channel channels in parallel.

In one embodiment, in at least one of the tempering modules, the channel comprises a series single-mode channel module, the series single-mode channel module comprises two main path channels and a plurality of branch path channels, and each branch path channel is connected in series between the two main path channels.

In one embodiment, each of the bypass channels is S-shaped.

In one embodiment, in at least one of the temperature conditioning modules, the channel comprises a series multimode channel module comprising at least two series single mode channel modules, each series single mode channel module connected in series with each other; the series single-mode channel module comprises two main path channels and a plurality of branch path channels, and each branch path channel is connected between the two main path channels in series.

In one embodiment, the main passage has a larger cross-sectional area in a direction perpendicular to its axis than the branch passage.

In one embodiment, the temperature regulating garment is formed of the same material by at least one of injection molding, compression molding, extrusion molding, compression injection molding, and blow molding.

Temperature-regulating device comprising a temperature-regulating garment as defined in any one of the above.

The temperature adjusting equipment comprises a temperature adjusting garment, and by arranging the plurality of channels, liquid with preset temperature can be input through the liquid inlet and flows into each channel, so that the heat preservation or cold insulation effect can be achieved, temperature adjustment is not needed to be carried out by increasing clothes or reducing the clothes, and the comfort, the working efficiency and the life quality of a user are improved. The temperature-adjusting clothes comprise a plurality of temperature-adjusting modules, different temperature-adjusting modules can be used according to the requirements of users, for example, the temperature-adjusting modules can be designed into sheet modules positioned at the positions of a front chest, a back and the like, can also be designed into shapes of sleeves, necklines and the like, and can also be designed into a vest shape, and each temperature-adjusting module can be directly and respectively attached to different parts of a human body or different parts of clothes through a binding band, a button, a zipper, sticky materials and the like, so that the use is convenient.

Drawings

FIG. 1 is a schematic view of a temperature regulating garment according to one embodiment;

FIG. 2 is a schematic diagram of a temperature adjustment module according to an embodiment;

FIG. 3 is a schematic view of a passage of a temperature module in a first embodiment;

FIG. 4 is a schematic view of a passage of a temperature conditioning module in a second embodiment;

FIG. 5 is a schematic view of a pathway of a temperature conditioning module in a third embodiment;

fig. 6 is a schematic view of a passage of a temperature module in a fourth embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In the description of the present application, it is to be understood that the terms "center", "lateral", "upper", "lower", "left", "right", "vertical", "horizontal", "top", "bottom", "inner" and "outer" etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present application. Further, when an element is referred to as being "formed on" another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present.

Fig. 1 is a schematic view of a temperature-adjusting garment in one embodiment. Fig. 2 is a schematic diagram of a temperature conditioning module in an embodiment. As shown in fig. 1 and 2, the temperature-adjusting clothes include a liquid inlet 11, a liquid outlet 12 and a plurality of temperature-adjusting modules 18. For example, the temperature control modules 18 may be designed as sheet modules at the front chest, the back, etc., or may be designed as sleeves, necklines, vests (see fig. 2), etc. Each temperature regulating module 18 may be attached to the human body or to the clothing directly by a strap, an adhesive material, or the like. Each temperature regulating module 18 is provided with a plurality of channels 13, the channels 13 are communicated with each other, and when the temperature regulating module 18 has enough liquid, the liquid can freely circulate among the channels 13. The cross-sectional area of each channel 13 can be set according to actual requirements. The temperature control modules 18 are connected in series, for example by means of pipes, so that all the passages 13 in the temperature control modules 18 are connected to each other, so that, when there is sufficient liquid in the temperature control garment, the liquid can freely flow between the temperature control modules 18. The liquid inlet 11 and the liquid outlet 12 are both arranged on the same temperature adjusting module 18 and communicated with each channel 13, or the liquid inlet 11 and the liquid outlet 12 are respectively arranged on two temperature adjusting modules 18 and communicated with each channel 13.

The liquid in the temperature-adjusting clothes can be set according to actual requirements, for example, water which is easy to heat or cool can be adopted.

Above-mentioned thermoregulation clothes is through setting up a plurality of passageways 13 to through inlet 11 to the interior liquid of predetermineeing the temperature of input of passageway 13 make liquid be full of each passageway 13, thereby can reach the effect of heat preservation or cold insulation, needn't carry out temperature regulation through increasing the clothing or reducing the clothing, thereby improve user's work travelling comfort, work efficiency and quality of life. Moreover, the temperature-adjusting clothes comprise a plurality of temperature-adjusting modules 18, different temperature-adjusting modules 18 can be used according to the requirements of users, for example, the temperature-adjusting modules 18 can be designed into sheet modules positioned at the positions of the front chest, the back and the like, can also be designed into shapes of sleeves, necklines and the like, and can also be designed into a vest shape, and each temperature-adjusting module 18 can be directly and respectively attached to different parts of the human body or different parts of the clothes through straps, buttons, zippers, sticky materials and the like, so that the use is convenient.

In an embodiment, taking water as an example, if a human body is to be cooled, water with a lower temperature is input into the temperature-adjusting clothes through the liquid inlet 11, after the water with the lower temperature flows through various parts of the human body through the temperature-adjusting clothes, the temperature of the water in the temperature-adjusting clothes will rise, the water in the temperature-adjusting clothes is directly discharged from the liquid outlet 12, and the water with the lower temperature can be continuously input into the temperature-adjusting clothes through the liquid inlet 11, so that the human body can be rapidly cooled by consuming enough water. If a human body needs to be heated, water with higher temperature is input into the temperature-adjusting clothes through the liquid inlet 11, after the water with higher temperature flows through each part of the human body through the temperature-adjusting clothes, the temperature of the water in the temperature-adjusting clothes is reduced, the water in the temperature-adjusting clothes is directly discharged from the liquid outlet 12, and the water with higher temperature can be continuously input into the temperature-adjusting clothes through the liquid inlet 11, so that the human body can be rapidly heated by consuming enough water. In other embodiments, valves may be disposed in the liquid inlet 11 and the liquid outlet 12, and the valves are closed when the temperature of the water in the temperature-adjusting clothes reaches a predetermined temperature, so as to stop the water supply to the temperature-adjusting clothes through the liquid inlet 11 and the water discharge from the temperature-adjusting clothes through the liquid outlet 12.

In another embodiment, the temperature-adjustable garment further comprises a liquid temperature adjusting device (not shown in the figures) for adjusting the temperature of the liquid, in particular for lowering the temperature of the liquid, and for raising the temperature of the liquid. The liquid inlet 11 and the liquid outlet 12 are both connected with a liquid temperature adjusting device, the liquid temperature adjusting device inputs liquid with preset temperature to the liquid inlet 11 and flows into each channel 13, and the liquid flows out of the liquid temperature adjusting device through the liquid outlet 12. Still taking water as an example, if a human body needs to be cooled, the liquid temperature adjusting device flows water with lower temperature into the temperature adjusting clothes through the liquid inlet 11, after the water with lower temperature flows through each part of the human body through the temperature adjusting clothes, the water temperature in the temperature adjusting clothes will rise, then the water in the temperature adjusting clothes flows back to the liquid temperature adjusting device from the liquid outlet 12, the water is cooled into water with lower temperature again through the liquid temperature adjusting device, and the water is injected into the temperature adjusting clothes through the liquid inlet 11 again, so that a certain amount of water is ensured to be circulated repeatedly until the temperature of the flowing water reaches or approaches to the preset temperature. If will heat the human body, liquid temperature adjusting device passes through inlet 11 to adjust the temperature clothing inflow temperature higher water, the lower high clothes that adjusts the temperature through adjusting the temperature behind each position of human body of flowing through, the temperature in the clothing that adjusts the temperature will reduce, then the water in the clothing that adjusts the temperature flows back to liquid temperature adjusting device from liquid outlet 12, is heated into the higher water of temperature once more through liquid temperature adjusting device, annotate the clothing that adjusts the temperature through inlet 11 once more, guarantee a certain amount of water recirculation, until the temperature of the water that flows out reaches or is close to preset temperature.

In a first embodiment, referring to fig. 1-3, in at least one of the temperature conditioning modules 18, the channel 13 comprises a parallel single-mode channel module 15. The parallel single-mode channel 15 includes two main channel 151 and a plurality of branch channels 152, and each branch channel 152 is connected in parallel between the two main channel 151.

In some examples, the liquid inlet 11 and the liquid outlet 12 are respectively connected with two main path channels 151 in the parallel single-mode channel module 15 of fig. 3, wherein the other end of one main path channel 151 can be connected with another temperature adjusting module 18. When the liquid circulates through the parallel single-mode channel module 15 shown in fig. 3, the liquid may first flow into the right main channel 151, then flow into each branch channel 152 through the right main channel 151, flow into the left main channel 151, flow into the remaining temperature adjustment modules 18 through the other end of one main channel 151, and finally flow into the liquid outlet 12 from the left main channel 151 and flow out.

In other examples, one of the inlet 11 and outlet 12 is connected to one of the two main passages 151 in fig. 3, for example, the right main passage 151 is connected to the inlet 11, the outlet 12 is disposed on any one of the remaining temperature control modules 18, and the left main passage 151 is connected to the other temperature control module 18.

In further examples, the liquid inlet 11 and the liquid outlet 12 are each connected to the remaining tempering modules 18, one main channel 151 of the parallel single-mode channel module 15 of fig. 3 is connected to another tempering module 18, or two main channels 151 of the parallel single-mode channel module 15 of fig. 3 are each connected to two further tempering modules 18.

In some examples, two main road channels 151 may be arranged in parallel or extension lines of two main road channels 151 may also intersect. The branch passages 152 may be arranged in parallel, or may be arranged such that extension lines of adjacent branch passages 152 intersect. Each of the branch channels 152 may be perpendicular to and intersect the main channel 151, and of course, each of the branch channels 152 may also be disposed to be oblique to the main channel 151, so that both ends of each of the branch channels 152 are respectively connected to two main channels 151. The cross-sections of the main passage 151 and the branch passage 152 in the respective axial directions may be circular, elliptical, rectangular, triangular, etc., and the cross-sectional shapes of both may be the same or different. The main passage 151 and the branch passage 152 may be linear, S-shaped, zigzag, or the like, and the shapes thereof may be the same or different. The branch channel 152 may be connected to a side of the main channel 151.

In some examples, the cross-sectional area of the main passage 151 in its axial direction is larger than the cross-sectional area of the branch passage 152 in its axial direction. Since the liquid flows into each of the branch passages 152 from the main passage 151, the sectional area of the main passage 151 in the axial direction thereof is larger than that of the branch passage 152 in the axial direction thereof, so that the time for filling each of the branch passages 152 with the liquid can be shortened; when liquid is to be discharged, the liquid in each branch passage 152 is discharged through the main passage 151, and since the sectional area of the main passage 151 in the axial direction thereof is larger than the sectional area of the branch passage 152 in the axial direction thereof, the liquid discharge time is also short, thereby facilitating improvement of the temperature regulation efficiency. In other examples, it may be also set such that the sectional area of the main passage 151 in the axial direction thereof is equal to the sectional area of the branch passage 152 in the axial direction thereof.

In some examples, at least some of the branch passages 152 may be disposed in an S-shape and horizontally, and the branch passages 152 are arranged in sequence in a vertical direction. For example, when the temperature-adjusting clothes are designed into a vest shape, the branch passages 152 at the armpit part can be arc-shaped so as to be fitted to the human body part, and the branch passages 152 at the other parts can be arranged in an S-shaped and horizontal manner so as to facilitate the liquid to flow through the temperature-adjusting clothes for a longer distance, so that the contact area between the branch passages 152 carrying the liquid and the human body is larger, thereby the heat or the cold is more balanced, and the human body is more comfortable. A plurality of hollowed-out shapes can be formed between adjacent S-shaped branch channels 152, and the hollowed-out shapes can be square, triangular, circular, prismatic, and the like.

In a second embodiment, and referring also to FIG. 4, in at least one of the temperature conditioning modules 18, the tunnel 13 comprises a parallel multi-mode tunnel module. The parallel multi-mode channel comprises at least two parallel single-mode channel modules 15, and the parallel single-mode channel modules 15 are communicated with each other. Referring to fig. 3, the parallel single-mode channel 15 includes two main path channels 151 and a plurality of branch channels 152, and each branch channel 152 is connected in parallel between the two main path channels 151. The parallel single-mode channel 15 can refer to the description in the first embodiment, and is not described here.

In some examples, inlet port 11 and outlet port 12 are connected to any two main channel channels 151 in the parallel multi-mode channel module of fig. 4, respectively. Any one main path channel 151 in the parallel multi-mode channel module is connected with another temperature adjusting module 18, or any two main path channels 151 in the parallel multi-mode channel module are respectively connected with the other two temperature adjusting modules 18.

In other examples, one of the inlet port 11 and the outlet port 12 is connected to any one of the main channels 151 of the parallel multi-mode channel module of fig. 4, and the other of the inlet port and the outlet port 12 is disposed on any remaining one of the temperature adjusting modules 18. Any one main channel 151 in the parallel multi-mode channel module of fig. 4 is connected to another temperature regulation module 18, or any two main channels 151 in the parallel multi-mode channel module are respectively connected to another two temperature regulation modules 18.

In still other examples, the liquid inlet 11 and the liquid outlet 12 are both disposed on any remaining temperature adjusting module 18 or disposed on any remaining two temperature adjusting modules 18 respectively. Any one main path channel 151 in the parallel multi-mode channel module of fig. 4 is connected to another temperature regulation module 18, or any two main path channels 151 are respectively connected to another two temperature regulation modules 18.

In some examples, the number of parallel single mode channel modules 15 in the parallel multimode channel module may be two or more. Taking the number of the parallel single-mode channel modules 15 in fig. 4 as an example, two parallel single-mode channel modules 15 may be placed side by side. The middle two main channels 151b and 151c are connected so that the two parallel single-mode channel modules 15 communicate with each other.

In some examples, the cross-sectional area of the main passage 151 in its axial direction is larger than the cross-sectional area of the branch passage 152 in its axial direction.

In a third embodiment, referring to fig. 1, 2 and 5, channel 13 comprises a series single mode channel module 16. The serial single-mode channel module 16 includes two main channels 161 and a plurality of branch channels 162, and each branch channel 162 is connected in series between the two main channels 161.

In some examples, the liquid inlet 11 and the liquid outlet 12 are respectively connected with two main channel channels 161 in the series single-mode channel module 16 of fig. 5, and the other end of one main channel 161 can also be connected with another temperature adjusting module 18. When the liquid circulates through the single-mode channel module 16 in series in fig. 5, the liquid may first flow into the right main channel 161, then flow into each branch channel 162 through the right main channel 161, flow into the left main channel 161, flow into the remaining temperature adjusting modules 18 through the other end of one main channel 161, and finally flow into the liquid outlet 12 and flow out from the left main channel 161.

In other examples, one of the inlet 11 and the outlet 12 is connected to one of the two main channels 161 shown in fig. 5, for example, the right main channel 161 is connected to the inlet 11, the outlet 12 is disposed on any one of the remaining temperature control modules 18, and the left main channel 161 is connected to the other temperature control module 18.

In further examples, both the liquid inlet 11 and the liquid outlet 12 are connected to the remaining tempering modules 18, one main channel 161 of the series single-mode channel module 16 of fig. 5 is connected to another tempering module 18, or two main channels 161 of the series single-mode channel module 16 of fig. 5 are connected to two further tempering modules 18, respectively.

In some examples, the two main path channels 161 may be arranged in parallel, or the extension lines of the two main path channels 161 may intersect. The branch channels 162 may be disposed in parallel, and each branch channel 162 may be parallel to the main channel 161. It may be arranged that the branch passages 162 intersect each other, and the two outermost branch passages 162 intersect the two outer main passages 161, respectively. Starting from the left side, the top end of the first branch channel 162 is connected with the top end of the main channel 161 on the left side, the tail end of the first branch channel 162 is connected with the tail end of the second branch channel 162, the top end of the second branch channel 162 is connected with the top end of the third branch channel 162, and so on, the top end of the last branch channel 162 is connected with the top end of the main channel 161 on the right side, so that each branch channel 162 is in an S-shaped arrangement. The cross-section of the main passage 161 and the branch passage 162 in the respective axial directions may be circular, elliptical, rectangular, triangular, etc., and the cross-sectional shapes thereof may be the same or different. The main channel 161 and the branch channel 162 may be linear, S-shaped, zigzag, or the like, and the shapes of the two may be the same or different.

In some examples, the cross-sectional area of the main passage 161 in the axial direction thereof is larger than the cross-sectional area of the branch passage 162 in the axial direction thereof. In this embodiment, the liquid first enters the main passage 161 and flows into each of the branch passages 162, and since the sectional area of the main passage 161 in the axial direction thereof is larger than the sectional area of the branch passage 162 in the axial direction thereof, the time for filling each of the branch passages 162 with the liquid can be shortened; when liquid is to be discharged, the liquid in each of the branch passages 162 is discharged through the main passage 161, and since the sectional area of the main passage 161 in the axial direction thereof is larger than the sectional area of the branch passage 162 in the axial direction thereof, the liquid discharge time is also short, thereby contributing to the improvement of the temperature regulation efficiency. In other examples, it may be also set so that the sectional area of the main passage 161 in the axial direction thereof is equal to the sectional area of the branch passage 162 in the axial direction thereof.

In a fourth embodiment, and referring also to fig. 6, in at least one of the trim modules 18, the tunnel 13 comprises a series multi-mode tunnel module. The tandem multimode channel module includes at least two tandem single mode channel modules 16, each tandem single mode channel module 16 being in tandem. Referring to fig. 5, the serial single-mode channel module 16 includes two main channels 161 and a plurality of branch channels 162, and each branch channel 162 is connected in series between the two main channels 161. The serial single-mode channel module 16 can refer to the description in the third embodiment, and is not described here.

In some examples, the liquid inlet 11 and the liquid outlet 12 are connected with any two main channel channels 161 in the series multimode channel module of fig. 6, respectively. Any one main path channel 161 in the series multi-mode channel module is connected with another temperature adjusting module 18, or any two main path channels 161 in the series multi-mode channel module are respectively connected with the other two temperature adjusting modules 18.

In other examples, one of the inlet port 11 and the outlet port 12 is connected to any one of the main channels 161 of the series multi-mode channel modules of fig. 6, and the other of the inlet port and the outlet port 12 is disposed on any remaining one of the temperature conditioning modules 18. Any one main channel 161 of the series multi-mode channel modules of fig. 6 is connected to another temperature regulating module 18, or any two main channels 161 of the series multi-mode channel modules are respectively connected to another two temperature regulating modules 18.

In still other examples, the liquid inlet 11 and the liquid outlet 12 are both disposed on any remaining temperature adjusting module 18 or disposed on any remaining two temperature adjusting modules 18 respectively. Any one main path channel 161 in the series multi-mode channel module of fig. 6 is connected with another temperature regulation module 18, or any two main path channels 161 are respectively connected with the other two temperature regulation modules 18.

In some examples, the number of series single mode channel modules 16 in the series multimode channel module may be two or more. Taking the example of fig. 6 where the number of the series single-mode channel modules 16 is two, the two series single-mode channel modules 16 can be placed side by side. The bottom ends of the middle two main channel 161b and the bottom end of 161c are connected so that the two series single-mode channel modules 16 communicate with each other. The outer two main passages 161a may be connected to the liquid outlet 12, and the main passage 161d may be connected to the liquid inlet 11. The liquid flows into the main channel 161d, then flows into each branch channel 162 of the right single-mode channel module 16, then flows into the main channel 161c, then flows into the main channel 161b, then flows into each branch channel 162 of the left single-mode channel module 16, then flows into the main channel 161a, and finally flows out.

In some examples, the cross-sectional area of the main passage 161 in the axial direction thereof is larger than the cross-sectional area of the branch passage 162 in the axial direction thereof. In other examples, it may be also set so that the sectional area of the main passage 161 in the axial direction thereof is equal to the sectional area of the branch passage 162 in the axial direction thereof.

It should be noted that the specific shape of the passage 13 is not limited to the specific shapes listed in the above first to fourth embodiments, but may be other shapes, and may also be any combination of the first to fourth embodiments.

In one embodiment, as shown in fig. 2, the temperature regulating garment may be made of a flexible waterproof material 14, and the flexible waterproof material 14 may be made into a specific shape such as the shape of a vest as shown in fig. 2, and the flexible waterproof material forms a plurality of channels 13 to contain liquid for cooling or heating. The flexible waterproof material is easily molded to be designed in various shapes, and can prevent the liquid in the passage 13 from overflowing. In other embodiments, the temperature conditioning module 18 may also be made of materials that are fire resistant, high temperature resistant, corrosion resistant, etc.

In one embodiment, the temperature-regulating garment is formed from the same material by at least one of injection molding, compression molding, extrusion molding, compression injection molding, and blow molding. The injection molding is to add plastic into a heating charging barrel of an injection machine, the plastic is heated and melted, a nozzle and a mold pouring system enter a mold cavity under the pushing of the injection machine or a plunger, and the plastic is hardened and molded into an injection molding product due to physicochemical and chemical effects. Compression molding is the process of adding plastic directly into an open mold cavity at a certain temperature, then closing the mold, and melting the plastic under heat and pressure to become a fluid state. Due to physical and chemical actions, the plastic is hardened into a plastic part with certain shape and size and unchanged at normal temperature. Extrusion molding is a molding method in which a plastic in a viscous flow state is passed through a die having a specific cross-sectional shape at a high temperature and a certain pressure, and then, at a lower temperature, is shaped into a continuous profile having a desired cross-sectional shape. The injection molding, also called transfer molding, is to add plastic raw materials into a preheated feeding chamber, then put a compression column into the feeding chamber to lock a mold, apply pressure to the plastic through the compression column, melt the plastic into a flowing state at high temperature and high pressure, and enter a cavity through a casting system to be gradually solidified into a plastic part. The hollow forming is a processing method in which a tubular or sheet blank which is prepared by extrusion or injection and is in a plasticized state is fixed in a forming die in a trend, compressed air is introduced immediately to force the blank to expand and be attached to the wall surface of a die cavity of the die, and the required hollow product is obtained after cooling, shaping and demoulding. In this embodiment, any one of the above-mentioned forming methods is adopted to form the temperature-adjusting clothes, rather than adopting the mode of burying a water pipe in the internal passage of the clothes to allow the liquid to circulate, so that the mass production efficiency of the temperature-adjusting clothes is greatly improved, the strength is higher, the service life is longer, and the temperature-adjusting clothes have certain elasticity and are suitable for the human body structures of different statures.

The application also provides a temperature regulating device. The temperature adjusting device comprises the temperature adjusting clothes in any one of the embodiments.

The temperature adjusting device comprises a temperature adjusting garment. The temperature-adjusting clothes are provided with the plurality of channels 13, and liquid with preset temperature is input into the channels 13 through the liquid inlet 11 to enable the liquid to fill the channels 13, so that the heat preservation or cold insulation effect can be achieved, temperature adjustment is not needed to be carried out through adding clothes or reducing the clothes, and the working comfort, the working efficiency and the life quality of a user are improved. Moreover, the temperature-adjusting clothes comprise a plurality of temperature-adjusting modules 18, different temperature-adjusting modules 18 can be used according to the requirements of users, for example, the temperature-adjusting modules 18 can be designed into sheet modules positioned at the positions of the front chest, the back and the like, can also be designed into shapes of sleeves, necklines and the like, and can also be designed into a vest shape, and each temperature-adjusting module 18 can be directly and respectively attached to different parts of the human body or different parts of the clothes through straps, buttons, zippers, sticky materials and the like, so that the use is convenient.

In one embodiment, the temperature-regulating garment includes a liquid temperature regulating device. Liquid temperature adjusting device can be connected with the clothing that adjusts the temperature and set up on the clothing that adjusts the temperature through inlet 11 and liquid outlet 12 to can heat or cool down the liquid in the clothing that adjusts the temperature at any time, liquid temperature adjusting device also can set up in the clothing outside that adjusts the temperature, and after liquid temperature adjusting device cooled down or heated the liquid in the clothing that adjusts the temperature, the last liquid inlet 11 of disconnection clothing that adjusts the temperature and liquid outlet 12 and liquid temperature adjusting device's connection, thereby lighten the weight that the user bore.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A temperature-adjusting garment is characterized by comprising a liquid inlet, a liquid outlet and a plurality of temperature-adjusting modules, wherein each temperature-adjusting module is provided with a plurality of channels, and the temperature-adjusting modules are sequentially connected to enable the channels in the temperature-adjusting modules to be communicated; the liquid inlet and the liquid outlet are arranged on the same temperature adjusting module and communicated with the channel, or the liquid inlet and the liquid outlet are respectively arranged on two temperature adjusting modules and communicated with the channel.

2. The temperature-regulated garment according to claim 1, further comprising a liquid temperature regulating device for regulating the temperature of the liquid; the liquid inlet and the liquid outlet are both connected with the liquid temperature adjusting device; the liquid temperature adjusting device inputs liquid with preset temperature to the liquid inlet and flows into the channels, and the liquid flows out from the liquid outlet to the liquid temperature adjusting device.

3. The temperature regulated garment of claim 1, wherein in at least one of said temperature regulating modules, said pathway comprises a parallel single-mode pathway module comprising two main pathway pathways and a plurality of branch pathways, each branch pathway connected in parallel between said two main pathway pathways.

4. The temperature regulating garment according to claim 1, wherein in at least one of said temperature regulating modules, said pathway comprises a parallel multi-modal pathway module, said parallel multi-modal pathway module comprises at least two parallel single-modal pathway modules, and each parallel single-modal pathway module is in communication therewith; the parallel single-mode channel module comprises two main channel channels and a plurality of branch channel channels, and each branch channel is connected between the two main channel channels in parallel.

5. A temperature conditioned garment according to claim 1, wherein in at least one of said temperature conditioning modules, said pathway comprises a series single-mode pathway module comprising two main pathway pathways and a plurality of branch pathways, each branch pathway connected in series between said two main pathway pathways.

6. The temperature-regulating garment of claim 5, wherein each bypass channel is S-shaped.

7. The temperature conditioned garment of claim 1, wherein in at least one of the temperature conditioning modules, the pathway comprises a series multi-mode pathway module comprising at least two series single-mode pathway modules, each series single-mode pathway module connected in series between; the series single-mode channel module comprises two main path channels and a plurality of branch path channels, and each branch path channel is connected between the two main path channels in series.

8. A temperature garment according to any one of claims 3 to 7, wherein the cross-sectional area of the main path channel in a direction perpendicular to its axis is greater than the cross-sectional area of the branch path channel in a direction perpendicular to its axis.

9. The temperature garment of claim 1, wherein the temperature garment is formed from the same material by at least one of injection molding, compression molding, extrusion molding, compression injection molding, and blow molding.

10. A temperature conditioning apparatus, comprising a temperature conditioning garment according to any one of claims 1 to 9.

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