Physical cooling clothes with water supplementing function
By combining physical cooling block structure and water replenishment structure into the physical cooling clothing, the problem of poor performance of existing physical cooling clothing in high-temperature environments is solved, achieving continuous cooling and moisture replenishment, making it suitable for use in high-temperature environments for extended periods.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 萧铭谦
- Filing Date
- 2025-03-10
- Publication Date
- 2026-07-03
AI Technical Summary
Existing physical cooling clothing has limited effectiveness in high-temperature environments, cannot effectively lower body temperature, and lacks hydration, making it impractical.
Design a physical cooling garment with a water replenishment function, combining a physical cooling block structure and a water replenishment structure. The physical cooling block structure absorbs and conducts heat through the freezing liquid inside, while the water replenishment structure provides a continuous water source support, achieving a more effective cooling effect.
It provides continuous cooling in high-temperature environments, improving ease of use and comfort, making it suitable for long-term high-temperature work or activities, and highly practical.
Smart Images

Figure CN224440475U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cooling equipment technology, and in particular to a physical cooling garment with a water replenishment function. Background Technology
[0002] Many physical cooling garments on the market use fans to aid in cooling. These fans remove heat from the body's surroundings through airflow, thus achieving a cooling effect. When a fan is turned on, it accelerates airflow, carrying away heat from the skin through contact with the skin, resulting in a temporary cooling sensation. However, this method of cooling with fans has its limitations, especially in high-temperature environments, where the effect is often unsatisfactory.
[0003] Fans rely on airflow for cooling, but when the ambient temperature is high, airflow is ineffective at lowering body temperature. Fans cannot change the temperature of the surrounding air; the airflow simply brings hot air into contact with the skin and carries away some heat, but it doesn't provide sufficient cooling. Especially in extremely hot weather, the effect of a fan becomes negligible, and may even make the wearer feel more stuffy. This is because the cooling effect provided by a fan is too small a temperature difference with the environment to create a sufficient cooling effect to effectively alleviate discomfort caused by high temperatures. Furthermore, this type of cooling clothing has limited functionality; if hydration is considered, the wearer must carry an additional water bottle, making it impractical.
[0004] Therefore, it is necessary to design a new structure to achieve a more effective cooling effect and improve the convenience and comfort of use. Compared with the traditional fan cooling method, it has a stronger cooling capacity in high-temperature environments, is suitable for the needs of long-term high-temperature work or activities, and is highly practical. Utility Model Content
[0005] The purpose of this invention is to overcome the shortcomings of the existing technology and provide a physical cooling garment with a water replenishment function.
[0006] To solve the above-mentioned technical problems, the purpose of this utility model is achieved through the following technical solution: providing a physical cooling garment with a water replenishment function, comprising: a cooling garment body, a physical cooling block structure, and a water replenishment structure, wherein the physical cooling block structure is installed on the cooling garment body, and the water replenishment structure is installed on the cooling garment body.
[0007] The further technical solution is as follows: the cooling garment body includes a back garment and a front garment, the upper end of the back garment is connected to the upper end of the front garment; the two sides of the back garment are connected to the two sides of the front garment by adjustment straps respectively.
[0008] A further technical solution is as follows: the physical cooling block structure is installed on the side of the front of the garment near the back of the garment.
[0009] The further technical solution is as follows: the front of the garment is provided with a number of first mounting bags on the side near the back of the garment, and the physical cooling block structure is placed in the first mounting bag.
[0010] A further technical solution is as follows: the physical cooling block structure is installed on the side of the back garment near the front of the garment.
[0011] The further technical solution is as follows: the back garment is provided with several second mounting bags on the side near the front garment, and the physical cooling block structure is placed in the second mounting bags.
[0012] A further technical solution is that the water-replenishing structure is installed on the side of the back garment away from the front garment.
[0013] The further technical solution is as follows: the water replenishment structure includes a water replenishment bag and a hose, the water replenishment bag is provided with an inlet and an outlet, and the inlet and outlet are connected to the hose.
[0014] The further technical solution is as follows: the back cover has a cavity with an upper opening, the opening is equipped with a zipper, and the water-replenishing structure is placed inside the cavity.
[0015] The further technical solution is that the other end of the hose is connected to a one-way water outlet device.
[0016] The advantages of this invention compared to existing technologies are as follows: This invention achieves a more effective cooling effect by combining a physical cooling block structure and a water replenishment structure; the water replenishment structure provides continuous water support, eliminating the need to carry an extra cup to hold water, and can provide a water source for the wearer, making it highly practical; the combination of the cooling garment body and the physical cooling block structure utilizes the physical cooling block structure to quickly lower body temperature; compared with traditional fan cooling methods, it does not rely on airflow, but rather achieves a more uniform cooling effect through the melting of ice inside the physical cooling block structure, making it suitable for use in high-temperature environments for extended periods; the overall design enhances the wearer's comfort and convenience, making it suitable for users who need to work or engage in activities at high temperatures for extended periods.
[0017] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. Attached Figure Description
[0018] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0019] Figure 1 A three-dimensional structural diagram of a physical cooling garment with a water-replenishing function provided for an embodiment of this utility model. Figure 1 ;
[0020] Figure 2 A three-dimensional structural diagram of a physical cooling garment with a water-replenishing function provided for an embodiment of this utility model. Figure 2 ;
[0021] Figure 3 A three-dimensional structural diagram of a physical cooling garment with a water-replenishing function provided for an embodiment of this utility model. Figure 3 ;
[0022] Figure 4 A three-dimensional structural diagram of a physical cooling garment with a water-replenishing function provided for an embodiment of this utility model. Figure 4 ;
[0023] Figure 5 A schematic diagram of the main structure of a physical cooling garment with a water-replenishing function provided in an embodiment of this utility model;
[0024] Figure 6 A rear view structural diagram of a physical cooling garment with a water replenishment function provided for an embodiment of this utility model;
[0025] Figure 7 A three-dimensional structural diagram of the physical cooling and heat-reducing block structure provided in this embodiment of the utility model;
[0026] Figure 8 A three-dimensional structural diagram of the physical cooling and heat-reducing block structure provided in this embodiment of the utility model, showing the structure with the top cover removed;
[0027] Figure 9 A bottom view of the physical cooling and deheating block structure provided in this embodiment of the utility model;
[0028] Figure 10 A cross-sectional structural diagram of the physical cooling and deheating block structure provided in this embodiment of the utility model;
[0029] Figure 11 A schematic diagram of the stacked structure of the two physical cooling and deheating blocks provided in this embodiment of the utility model;
[0030] Figure 12A three-dimensional structural diagram of the valve seat provided in the embodiment of this utility model. Figure 1 ;
[0031] Figure 13 A three-dimensional structural diagram of the valve seat provided in the embodiment of this utility model. Figure 2 ;
[0032] Explanation of the markings in the image:
[0033] 1. Physical cooling block structure; 2. Front jacket; 3. Back jacket; 4. Shoulder straps; 5. Hydration bag; 6. Hose; 7. First mounting bag; 8. Second mounting bag; 9. Connector; 10. Top cover; 11. Bottom shell; 111. Cavity; 12. Connecting plate; 20. Guide channel; 30. Shell; 31. Mounting groove; 40. Valve seat; 41. Groove; 42. Recessed part; 50. Spherical protrusion; 60. Thermal insulation cotton; 70. Adjustment belt. Detailed Implementation
[0034] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.
[0035] It should be understood that, when used in this specification and the appended claims, the terms "comprising" and "including" indicate the presence of the described features, integrals, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more other features, integrals, steps, operations, elements, components and / or collections thereof.
[0036] It should also be understood that the terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the scope of the invention. As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” are intended to include the plural forms unless the context clearly indicates otherwise.
[0037] It should also be further understood that the term "and / or" as used in this specification and the appended claims refers to any combination of one or more of the associated listed items and all possible combinations, and includes such combinations.
[0038] Many physical cooling garments use fans to help lower body temperature, drawing heat away from the skin through airflow. When the fan is on, the increased airflow provides a temporary cooling sensation. However, fan cooling is limited in high-temperature environments and cannot effectively lower body temperature. Fans rely on airflow, but cannot change the ambient temperature in high temperatures. Especially in extremely hot weather, the cooling effect of fans is weak and may even increase the feeling of stuffiness. Furthermore, these cooling garments have relatively limited functionality; if hydration is considered, the wearer must carry an additional water bottle, making them impractical.
[0039] Therefore, this utility model provides a physical cooling garment with a water replenishment function, which achieves a more effective cooling effect and improves the convenience and comfort of use; compared with the traditional fan cooling method, it has a stronger cooling capacity in high temperature environments, is suitable for the needs of long-term high-temperature work or activities, and is highly practical.
[0040] Specifically, the physical cooling garment with hydration function provides a stronger cooling effect by combining the physical cooling block structure 1 and the hydration structure. The physical cooling block structure 1 contains a quick-freezing liquid that can rapidly absorb and conduct heat, helping to lower body temperature. The hydration structure, through the adjustable hose 6 and the hydration bag 5, ensures a continuous cooling effect and enhances wearing comfort. Compared with traditional fan cooling methods, this garment does not require a power source, making it suitable for prolonged work or activities in high temperatures. It is more convenient to use and does not rely on external equipment. The overall design emphasizes convenience and comfort, improving adaptability to high-temperature environments.
[0041] To better understand the above technical solutions, the following will provide a detailed explanation of the technical solutions in conjunction with the accompanying drawings and specific implementation methods.
[0042] Please see Figures 1 to 6 The aforementioned physical cooling garment with water replenishment function includes: a cooling garment body, a physical cooling block structure 1, and a water replenishment structure. The physical cooling block structure 1 is installed on the cooling garment body, and the water replenishment structure is installed on the cooling garment body.
[0043] In this embodiment, the cooling garment body is the basic structure of the entire cooling garment, supporting and housing other components, including physical cooling blocks and moisturizing structures. The cooling garment body is typically made of lightweight, breathable materials to maintain comfort and support prolonged wear.
[0044] The cooling garment is made of lightweight and breathable high-performance fabric (such as polyester or nylon), which effectively promotes air circulation and helps keep the body dry and comfortable.
[0045] Of course, it can also be set as insulation cotton to avoid the cooling effect being insignificant.
[0046] The cooling garment features a compact and well-fitting design, ensuring the wearer's flexibility during movement or activity. Furthermore, considering high-temperature environments, the collar, cuffs, and hem may incorporate adjustable features to allow for fine-tuning to suit different needs.
[0047] The physical cooling block structure 1 is the core component of the cooling garment, helping the wearer stay cool by lowering the temperature. The key design features of the physical cooling block are its rapid cooling and long-lasting effect.
[0048] The physical cooling block structure 1 is combined with the cooling garment body through a specific installation bag. The installation position is usually located in the front chest and back sides, which are close to the temperature regulation area of the body surface, so as to maximize the cooling effect.
[0049] The physical cooling block structure 1 can be composed of multiple independent modules, which are easy to replace and adjust. For example, one cooling block can be set in the front chest area, and two cooling blocks can be set in the back area to ensure that the chest and back areas can receive continuous cooling.
[0050] Physical cooling blocks typically use heat-absorbing materials (e.g., gels or special hydrogels) to absorb ambient heat through physical principles, thus lowering the temperature inside the clothing. These cooling blocks are often pre-treated through methods such as freezing to achieve a lower temperature, allowing for rapid cooling when worn.
[0051] The physical cooling block structure 1 is designed as a replaceable component, allowing users to remove it from the installation bag when needed, freeze it, and then place it back inside their clothing. This design ensures that the cooling effect can last for a longer period without worrying about the cooling block's effectiveness diminishing.
[0052] The hydration structure is designed to enhance the cooling effect and maintain the wearer's body moisture by continuously replenishing water to prevent dehydration caused by high temperatures.
[0053] The hydration structure is typically installed on the back of the cooling garment, away from the chest area where the physical cooling block structure 1 is located. This design ensures that the hydration and cooling functions are independent and do not interfere with each other, providing hydration for the wearer without the need to carry an extra water bottle, making it highly practical.
[0054] The hydration structure includes one or more hydration bags 5, which are typically made of flexible material and have adjustable capacity. The hydration bags 5 can store cold water or other cooling liquids, and the bags are usually designed for easy replacement and cleaning.
[0055] The water supply bag 5 is fed and discharged through the hose 6; the hose 6 is designed to be soft and easy to move, ensuring that the water can be evenly delivered to the cooling garment body.
[0056] The moisture inside the hydration bag 5 can maintain the wearer's water balance and reduce dehydration caused by excessive sweating in high-temperature environments.
[0057] Hydrating structures typically have an adjustment function, allowing wearers to hydrate according to their own needs and ensure optimal comfort under different environmental conditions.
[0058] The cooling garment body, the physical cooling block structure 1, and the water replenishment structure are carefully designed and integrated to form a multi-functional cooling system, which aims to provide the wearer with efficient and continuous cooling and hydration.
[0059] This physical cooling garment with hydration function provides efficient temperature control and hydration through the organic combination of the garment body, physical cooling block structure 1, and hydration structure. It is suitable for people who work or engage in activities in high-temperature environments for extended periods. Through the cooling effect of the physical cooling block structure 1 and the hydration of the hydration structure, this cooling garment can effectively regulate body temperature in hot environments, maintain the wearer's comfort, and help prevent dehydration or heatstroke caused by high temperatures.
[0060] In one embodiment, please refer to Figures 1 to 6 The cooling garment body includes a back cover 3 and a front cover 2, with the upper end of the back cover 3 connected to the upper end of the front cover 2. The two sides of the back cover 3 are connected to the two sides of the front cover 2 by adjustment straps 70.
[0061] In this embodiment, the cooling garment consists of two parts: a back cover 3 and a front cover 2. The upper ends of the two parts are connected by stitching or other methods to form a single garment. The front cover 2 can be a single piece or two separate pieces. In the latter case, the two front covers 2 can be connected by a zipper or a bag-style buckle structure.
[0062] The upper end of the front bra 2 is connected to the upper end of the back bra 3, which can be done by sewing or by using adjustable connecting devices (such as buttons, zippers, Velcro, etc.). This design ensures the integrity of the cooling garment and the comfort of the wearer. The combination of the front bra 2 and the back bra 3 gives the entire cooling garment sufficient flexibility to adapt to the wearing needs of different body types.
[0063] The front bra 2 and back bra 3 are typically made of breathable, lightweight fabrics to ensure the wearer stays dry and comfortable during activity, while having sufficient strength to support the weight of the physical cooling block structure 1 and the hydration system.
[0064] In one embodiment, please refer to Figures 1 to 6 The physical cooling block structure 1 is installed on the side of the front of the garment 2 near the back of the garment 3.
[0065] In one embodiment, please refer to Figures 1 to 6The physical cooling block structure 1 is installed on the side of the back garment 3 near the front garment 2.
[0066] In one embodiment, please refer to Figures 1 to 6 Several first mounting bags 7 are provided on the side of the front chest garment 2 near the back garment 3, and the physical cooling block structure 1 is placed in the first mounting bags 7.
[0067] In one embodiment, please refer to Figures 1 to 6 Several second mounting bags 8 are provided on the side of the back garment 3 near the front garment 2, and the physical cooling block structure 1 is placed in the second mounting bags 8.
[0068] In this embodiment, the physical cooling block structure 1 is the core cooling component of the cooling garment, which lowers the temperature of the clothing and the wearer by absorbing heat. In this embodiment, the physical cooling block is designed to be installed at the connection point between the front bodice 2 and the back bodice 3, i.e., close to the side of both.
[0069] The physical cooling block structure 1 is installed on the side of the front bra 2 near the back bra 3. This means that the physical cooling block is located in the wearer's chest area, enabling it to quickly sense and regulate body temperature, especially in high-temperature environments, helping to lower the wearer's core temperature. The contact area between the physical cooling block and the front bra 2 forms a temperature exchange zone, allowing the cooling effect of the cooling block to act more directly on the wearer's body.
[0070] The physical cooling block structure 1 can also be installed on the side of the back garment 3 near the front garment 2. This position is designed with the body's temperature distribution in mind. The back is one of the key areas for heat dissipation. Therefore, placing the physical cooling block on the back garment 3 near the front garment 2 can effectively regulate the temperature of the back and help the wearer stay comfortable.
[0071] To facilitate the installation and removal of the physical cooling blocks, the cooling garment is designed with an installation bag. The installation bag can hold the physical cooling blocks and keep them in a stable position, preventing the cooling blocks from moving or falling off during use.
[0072] The front of the vest 2 has several first mounting pockets 7 on the side near the back of the vest 3 for housing and securing the physical cooling block structure 1. These pockets are generally located on both sides of the front chest area to ensure that the cooling block can directly contact the skin and exert a cooling effect when worn. Each pocket is usually designed with an opening, zipper, or other closure to facilitate the removal and replacement of the physical cooling block.
[0073] Several second mounting pockets 8 are provided on the side of the back jacket 3 near the front jacket 2 to accommodate and secure the physical cooling block structure 1. These mounting pockets are typically located in the back area, providing support and securing the physical cooling block, which allows the physical cooling block structure 1 to continuously and effectively cool down.
[0074] When the physical cooling block structure 1 is placed inside the mounting pockets of the front vest 2 and the back vest 3, it can be secured by specific guide grooves or slots to prevent displacement during use. This design ensures that the cooling block is always kept in the ideal position, thereby improving cooling efficiency.
[0075] Since the physical cooling block structure 1 can be replaced as needed, the wearer can remove the cooling block when cooling is no longer required, or replace it with a new physical cooling block structure 1 when it fails. Furthermore, the installation bag design facilitates cleaning, preventing stains or water accumulation inside the physical cooling block structure 1 caused by long-term use.
[0076] By incorporating multiple mounting pockets on the sides of the front and back garments (2 and 3), and strategically placing the physical cooling block structure 1 within these pockets, the cooling garment can simultaneously provide cooling to multiple areas. This design ensures that the wearer's chest, back, and other high-temperature areas receive uniform cooling, thereby achieving optimal cooling performance.
[0077] The physical cooling block structure 1 of the front bra 2 and back bra 3, through optimized position and installation method, can continuously reduce the temperature when the wearer is active, helping the wearer to cope with long-term high temperature environment.
[0078] With the independent design and connection of the front bra 2 and the back bra 3, the cooling garment can be adjusted according to the needs of different users, providing a more flexible and comfortable wearing experience.
[0079] In actual use, the cooling effect can be improved by adjusting the adjustment belt 70 so that the physical cooling block structure at different positions is closer to the human body.
[0080] In this embodiment, the cooling garment effectively secures the physical cooling blocks to the sides of the front chest garment 2 and the back garment 3 via carefully designed first mounting pockets 7 and second mounting pockets 8. This allows the cooling blocks to continuously operate in the wearer's core area, providing uniform cooling. Furthermore, the designed mounting pockets simplify the replacement and cleaning of the physical cooling blocks, enhancing the garment's practicality and user experience. In this way, the cooling garment provides continuous and effective cooling, making it particularly suitable for work and activities in high-temperature environments.
[0081] In one embodiment, please refer to Figures 1 to 6 The water-replenishing structure is installed on the side of the back garment 3 away from the front garment 2.
[0082] In one embodiment, please refer to Figures 1 to 6 The water replenishment structure includes a water replenishment bag 5 and a hose 6. The water replenishment bag 5 is provided with an inlet and an outlet, which are connected to the hose 6.
[0083] In addition, the other end of the hose 6 is connected to a one-way water outlet device to prevent water in the hydration bag 5 from leaking out of the hose 6 due to vibration during exercise.
[0084] In one embodiment, please refer to Figures 1 to 6 The upper end of the back bra 3 is connected to the upper end of the front bra 2 via shoulder straps 4, and the flexible tube 6 is connected to the shoulder straps 4 via a connector 9. The connector 9 can be a fixing strap, etc.
[0085] In this embodiment, the hydration structure is installed on the side of the back garment 3 away from the front garment 2. This design aims to ensure that the hydration bag 5 functions properly on the wearer's back without interfering with the cooling function of the front garment 2.
[0086] The installation of the hydration bag 5 will not interfere with the structure of the front bra 2, thus avoiding affecting the cooling effect.
[0087] The hydration structure typically consists of two parts: a hydration bag (5) and a hose (6), and is designed with inlet and outlet ports. The connection and functional configuration of these components ensure that the hydration structure can continuously supply water to the cooling clothing, further enhancing the cooling effect.
[0088] The hydration bag 5 is typically designed as a flexible container that can hold a certain amount of water, and its size and placement usually depend on the wearer's activity needs and the comfort of the clothing. The hydration bag 5 is installed on the side of the back garment 3 away from the front garment 2 for easy access and contact with the wearer's back area.
[0089] The water supply bag 5 has an inlet and an outlet. The inlet is used to fill the water supply bag 5 with water, and the outlet is used to deliver the water to other parts of the cooling clothing (such as physical cooling blocks or other cooling areas). The outlet is usually connected to a hose 6 to ensure that water can flow into the designated location.
[0090] In this embodiment, the inlet and outlet can be the same hole.
[0091] The hose 6 is the core component that connects the hydration bag 5 to other parts of the cooling clothing, and is responsible for delivering water to the required area.
[0092] The hose 6 is typically designed to be flexible and durable, bending according to the wearer's movements without easily breaking. It is long enough to bend and stretch freely, ensuring the hydration bag 5 can be installed away from the chest bra 2 without hindering the wearer's movement.
[0093] The flexible tube 6 is connected to the shoulder strap 4 via the connector 9. The shoulder strap 4, as a crucial component when the wearer puts on clothing, secures the flexible tube 6 in the correct position via the connector 9, preventing it from swinging or experiencing excessive tension. When needed, the wearer can easily adjust the direction of the flexible tube 6 to ensure it does not obstruct movement.
[0094] Shoulder straps 4, as an important component of the cooling garment, not only connect the front of the garment 2 and the back of the garment 3, but also support the hydration structure and hoses 6.
[0095] The upper ends of the front bodice 2 and the back bodice 3 are connected by shoulder straps 4, ensuring that the wearer can easily put on and take off the clothing. At the same time, the connection design of shoulder straps 4 ensures that the flexible tube 6 is connected to the shoulder straps 4 via connector 9, preventing the flexible tube 6 from swinging around. Shoulder straps 4 provide a fixed point, making the position of the flexible tube 6 more stable and preventing it from falling off or becoming interfering due to the wearer's movements.
[0096] Connector 9 is the securing component between the hose 6 and the shoulder strap 4, ensuring a tight connection between the two. The design of connector 9 typically takes the wearer's comfort into account; it needs to be strong enough to support the hose 6 without causing discomfort or inconvenience to the wearer.
[0097] The water-replenishing structure design allows the cooling garment to maintain its cooling effect even during prolonged wear. The specific working principle is as follows:
[0098] The hydration bag 5 provides water to the cooling clothing on the wearer's back, and the water flows through the hose 6 to different parts of the cooling system.
[0099] The water inlet of the water bag 5 can be filled with water through an external water supply device (such as a water bottle or water source) to ensure that there is always enough water in the water bag 5.
[0100] The hose 6 is connected to the hydration bag 5 and securely attached to the shoulder strap 4 via the connector 9, ensuring that the hose 6 will not cause discomfort or hinder movement during use.
[0101] Water is continuously delivered through hose 6 so that the wearer can drink it, helping the wearer stay comfortable in high-temperature environments.
[0102] The overall design of the hydration structure not only enhances the functionality of the cooling garment but also improves the wearer's user experience:
[0103] The combination of the hydration structure and the physical cooling block significantly improves cooling efficiency, allowing the wearer to maintain a lower body temperature in hot environments. The shoulder strap 4 connection design provides stable support, preventing interference between the hydration bag 5 and the hose 6 during wear. The flexibility of the hose 6 ensures that the wearer's freedom of movement is not restricted during activity. The water inlet design of the hydration bag 5 and the adjustability of the hose 6 make hydration simple and convenient, allowing the wearer to replenish water as needed and maintain the normal operation of the cooling system.
[0104] In this embodiment, the hydration structure cleverly combines the hydration bag 5 and the hose 6, and installs them on the side of the back garment 3 away from the front garment 2, ensuring a long-lasting and stable cooling effect. Through the design of the shoulder straps 4 and connectors 9, the hose 6 is more stably connected to the other parts of the cooling garment, providing the wearer with a more comfortable and efficient experience. The hydration structure further enhances the functionality of the cooling garment, making it suitable for prolonged use in high-temperature environments.
[0105] In addition, the back cover 3 has a cavity with an opening at the top, the opening is equipped with a zipper, and the water-replenishing structure is placed inside the cavity.
[0106] After the water-filling structure is filled with water, it can be placed in a refrigerator to cool down. When in use, it can be placed in the cavity to transfer the cooling effect generated by the water melting process of the water-filling structure to the physical cooling block structure 1, and then to the human body, so as to improve the cooling effect of the entire cooling garment.
[0107] In one embodiment, please refer to Figure 7 The physical cooling block structure 1 includes a cooling block structure body and a freezing liquid. The cooling block structure body includes a bottom shell 11 and a top cover 10. The bottom shell 11 has an opening at its upper end, and the top cover 10 is assembled at the opening. The bottom shell 11 and the top cover 10 enclose a cavity 111, which is filled with freezing liquid.
[0108] In one embodiment, the material of the top cover 10 is, but is not limited to, TPU.
[0109] In one embodiment, the material of the bottom shell 11 is, but is not limited to, TPU.
[0110] In this embodiment, the top cover 10 and bottom shell 11 are made of TPU material, and the freezing liquid is perfectly sealed within the internal cavity 111 through a sealing design. The excellent sealing properties of TPU ensure that the liquid will not leak out, which means that the product can be repeatedly cleaned and reused after use, greatly improving the product's economy and sustainability. In addition to saving costs, this design also conforms to the concept of environmental protection, reducing unnecessary waste. Users can use the same cooling equipment multiple times without frequent replacement, greatly improving the product's cost-effectiveness.
[0111] In one embodiment, please refer to Figure 10 The cavity 111 contains thermal insulation cotton 60.
[0112] In this embodiment, the upper cover 10 and the lower cover, serving as the main protective shell 30 of the entire structure, are made of TPU material, possessing excellent flexibility and sealing performance. Thermal insulation cotton 60 is placed within the cavity 111 to enhance the product's insulation effect, ensure uniform distribution of cold energy, and extend the effective working time. Freezing liquid fills the cavity 111 formed by the upper cover 10 and the bottom shell 11, achieving cooling through a physical phase change.
[0113] Most existing antipyretic products lack insulation, resulting in rapid heat dissipation and an inability to maintain a cooling effect for an extended period. When used by patients, the rapid cooling effect weakens quickly, failing to provide a lasting cooling experience. In this embodiment, an important material, thermal insulation cotton 60, is added. After the frozen liquid is poured in, the thermal insulation cotton 60 absorbs a large amount of liquid and freezes in a refrigerator. Once the frozen liquid turns into ice, the thermal insulation cotton 60 has two main functions: it effectively prevents the influence of external temperature on the frozen liquid, avoiding accelerated melting due to external temperature changes, thereby extending the insulation time. Frozen liquid is fluid in its liquid state, causing some areas to freeze while others remain at room temperature. Without the thermal insulation cotton 60, uneven cooling may occur in different parts of the patient's body, affecting the effectiveness of the product. The thermal insulation cotton 60, through its ability to absorb frozen liquid, ensures even distribution of the ice, preventing the adverse effects of uneven temperature.
[0114] This design not only extends the cooling time but also ensures more even and effective cooling of the human body. When a patient's body temperature is high, the rapidly cooling liquid will quickly change from a solid to a liquid state at the point of contact with the body, while the thermal insulation cotton 60 makes the cooling process gentler, reduces the impact on the body, and prolongs the cooling effect.
[0115] In one embodiment, please refer to Figure 7 The aforementioned physical cooling and heat-reducing block structure also includes a raised structure, which is disposed on the outer wall of the heat-reducing structure body. Specifically, the raised structure includes several spherical protrusions 50. The raised structure is disposed on the outer wall of the bottom shell 11 away from the top cover 10.
[0116] In this embodiment, a unique raised structure is specially designed to prevent multiple physical cooling and heat dissipation block structures from sticking together during the freezing process. Specifically, several spherical protrusions 50 are provided on the outer wall of the heat dissipation structure body. These spherical protrusions 50 ensure that the multiple heat dissipation blocks placed in the freezing environment only have point contact, rather than surface contact, thereby effectively avoiding their sticking due to low temperature. This design not only simplifies the user's handling process but also improves the user experience. It not only effectively prevents product sticking but also reduces product loss rate, making the physical cooling and heat dissipation block structure more durable and extending the overall service life of the product.
[0117] In one embodiment, please refer to Figures 7 to 9 The number of bottom shells 11 is at least two, and there is a gap between two adjacent bottom shells 11, and the two adjacent bottom shells 11 are connected by a flow guiding structure.
[0118] In one embodiment, please refer to Figures 7 to 10 The two adjacent bottom shells 11 are connected by a connecting plate 12, and the flow guiding structure is disposed on the connecting plate 12. The material of the connecting plate 12 is, but is not limited to, TPU.
[0119] In one embodiment, please refer to Figures 7 to 9 The aforementioned flow guiding structure includes several flow guiding grooves 20, which are spaced apart on the connecting plate 12.
[0120] In one embodiment, the number of the above-mentioned flow guide grooves 20 is three.
[0121] This embodiment employs a gap between the side walls of the two bottom shells 11, through which a connecting plate 12 made of TPU is placed. The side walls of the two bottom shells 11 are connected by the connecting plate 12, which has three flow channels 20. The flow channels 20 not only help guide the liquid and accelerate its distribution during rapid freezing, but also assist in bending. Specifically, during the rapid freezing process, the distribution of the frozen liquid is not completely uniform. Although the areas on both sides cannot be bent due to the excessive thickness of the ice, the middle part, due to the presence of the flow channels 20, has less frozen liquid, thus allowing this part to remain flexible and bendable.
[0122] The ingenious design of the flow channel 20 lies in its ability to guide the rapid-cooling liquid to flow evenly, while simultaneously ensuring that the ice layer within the channel is significantly thinner than the ice blocks on either side when the liquid freezes. This varying hardness in localized areas ensures that the product retains its flexibility in the middle after freezing, allowing it to be bent even after rapid freezing. This design not only improves the product's flexibility, enabling it to adapt to different body shapes or applications requiring bending, but also avoids the problem of traditional cooling blocks becoming too hard and inflexible after freezing. Users can bend the product according to their needs to fit different parts of the body, providing a more comfortable and comprehensive cooling effect.
[0123] In one embodiment, please refer to Figure 10 , Figure 12 and Figure 13 The physical cooling and heat-reducing blockage also includes a valve seat 40. The heat-reducing structure body is provided with an installation groove 31, and the valve seat 40 is assembled in the installation groove 31.
[0124] In one embodiment, please refer to Figure 10 The side of the valve seat 40 near the mounting groove 31 is recessed in a direction away from the mounting groove 31, forming a groove 41. In addition, in order to facilitate the removal and installation of the valve seat 40, the outer side wall of the valve seat 40 is recessed inward, forming a number of recesses 42, which the user can hold to remove or install the valve seat 40.
[0125] In one embodiment, please refer to Figure 8 There are two bottom shells 11. One of the bottom shells 11 has a housing 30 inside. The upper end of the housing 30 is recessed downward to form a mounting groove 31. The mounting groove 31 is connected to the two bottom shells 11 through a guide groove 20.
[0126] In one embodiment, the valve seat 40 is made of, but is not limited to, TPU.
[0127] Many quenching and cooling products on the market cannot be refilled or refilled once the quenching liquid freezes. This means that users can only use them once, and the cooling effect is greatly reduced afterward. For these products, once the quenching liquid turns into ice, the product's use is over and cannot be replenished or reused.
[0128] This embodiment successfully solves this problem by employing a mating structure of valve seat 40, guide groove 20, upper cover 10, and bottom shell 11, allowing users to refill the quenching liquid. The toughness of the TPU material used for the valve seat 40 ensures a tight fit with the upper cover 10 and bottom shell 11, effectively sealing the liquid. When the user inserts a syringe needle into the center of the valve seat 40, the elastic properties of the valve seat 40 ensure that the needle can enter smoothly, and after the needle is withdrawn, the valve seat 40 automatically returns to its original shape, completing the seal and ensuring that the quenching liquid does not leak. It should be noted that the needle passes through the aforementioned groove 41.
[0129] Furthermore, the design of four flow channels 20 and the cooperation of the mounting slots 31 ensure that the quenching liquid can quickly flow to all areas of the physical cooling and heat-reducing block structure after injection, thereby achieving a uniform and rapid cooling effect. This structure not only facilitates the liquid injection operation during the production process, but also ensures that the product can be refilled with quenching liquid after each use, enabling multiple reuses.
[0130] This design allows users to inject and replace the liquid as needed, improving product reusability, saving production costs, and reducing waste. Furthermore, users don't need to discard cooled products; they can restore their original cooling effect and continue using them by injecting new quenching liquid.
[0131] Traditional physical cooling blocks, once frozen, become rigid and brittle, unable to be bent or deformed due to the complete freezing of the liquid. Once the coolant turns to ice, the product retains its hardness and cannot adapt to certain special shape requirements. This embodiment addresses this by creating a gap between the side walls of the two base shells 11, through which a TPU connecting plate 12 is placed. The side walls of the two base shells 11 are connected by the connecting plate 12, which has three flow channels 20. These channels not only help guide the liquid, accelerating its distribution during rapid freezing, but also assist in bending. Specifically, during the rapid freezing process, the distribution of the frozen liquid is not entirely uniform. While the outer areas are too thick to bend due to the ice, the middle section, due to the presence of the flow channels 20, has less frozen liquid, allowing it to remain flexible and bendable.
[0132] The ingenious design of the flow channel 20 lies in its ability to guide the rapid-cooling liquid to flow evenly, while simultaneously ensuring that the ice layer within the channel is significantly thinner than the ice blocks on either side when the liquid freezes. This varying hardness in localized areas ensures that the product retains its flexibility in the middle after freezing, allowing it to be bent even after rapid freezing. This design not only improves the product's flexibility, enabling it to adapt to different body shapes or applications requiring bending, but also avoids the problem of traditional cooling blocks becoming too hard and inflexible after freezing. Users can bend the product according to their needs to fit different parts of the body, providing a more comfortable and comprehensive cooling effect.
[0133] In this embodiment, the thermal insulation cotton 60 and the valve seat 40 are placed into the bottom shell 11 and the mounting groove 31, and the valve seat 40 and the thermal insulation cotton 60 are sealed after the top cover 10 and the bottom shell 11 are closed. Then, freezing liquid is poured in through the valve seat 40, filling the entire cavity 111. The entire physical cooling and heat-reducing block structure is placed in a freezer to cool until the internal freezing liquid completely freezes into ice. When in use, the frozen physical cooling and heat-reducing block structure is removed and attached to the body part requiring cooling to achieve its effect.
[0134] The aforementioned physical cooling and heat-reducing block structure, through its design, forms a sealed cavity 111 between the bottom shell 11 and the top cover 10, filled with freezing liquid, effectively maintaining the cooling effect. The opening design at the top of the bottom shell 11 allows the top cover 10 to be disassembled for easy cleaning and maintenance. The use of durable materials, such as TPU, increases the product's durability and reusability, reducing replacement frequency. Its simple structure, easy disassembly and cleaning, reduces long-term maintenance costs, and its reusable nature makes the product environmentally friendly, reducing resource waste and consumption.
[0135] The aforementioned physical cooling garment with hydration function achieves a more effective cooling effect by combining the physical cooling block structure 1 and the hydration structure. The hydration structure provides a continuous water source, eliminating the need to carry an extra cup and providing water for the wearer, making it highly practical. The combination of the cooling garment body and the physical cooling block structure 1 utilizes the physical cooling block structure 1 to quickly lower body temperature. Compared with traditional fan cooling methods, it does not rely on airflow but instead uses the melting of ice inside the physical cooling block structure 1 to bring a more uniform cooling effect, making it suitable for use in high-temperature environments for extended periods. The overall design enhances the wearer's comfort and convenience, making it suitable for users who need to work or engage in activities in high temperatures for extended periods.
[0136] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any person skilled in the art can easily conceive of various equivalent modifications or substitutions within the technical scope disclosed in this utility model, and these modifications or substitutions should all be covered within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the scope of the claims.
Claims
1. A physical cooling garment with water replenishment function, characterized in that, include: The cooling garment comprises a main body, a physical cooling block structure, and a water replenishment structure. The physical cooling block structure and the water replenishment structure are mounted on the main body of the cooling garment. The main body of the cooling garment includes a back cover and a front cover, with the upper end of the back cover connected to the upper end of the front cover. The two sides of the back cover and the two sides of the front cover are connected by adjustment straps. The water replenishment structure includes a water bag and a hose. The water bag has inlet and outlet ports, which are connected to the hose. The other end of the hose is connected to a one-way outlet device. The physical cooling block structure includes a bottom shell, a top cover, and a freezing liquid filled between the bottom shell and the top cover. A sealed cavity is formed between the bottom shell and the top cover, and thermal insulation cotton is also provided inside the sealed cavity. The physical cooling block structure also includes a protruding structure, which is disposed on the outer wall of the physical cooling block structure body. The physical cooling block structure also includes a valve seat, with an installation groove inside the physical cooling block structure body, into which the valve seat is assembled.
2. The physical cooling garment with water supplementing function according to claim 1, characterized in that, The physical cooling block structure is installed on the side of the front of the garment near the back.
3. The physical cooling garment with water supplementing function according to claim 2, characterized in that, The front of the garment has several first mounting pockets on the side near the back of the garment, and the physical cooling block structure is placed in the first mounting pocket.
4. The physical cooling garment with water supplementing function according to any one of claims 1 to 3, characterized in that, The physical cooling block structure is installed on the side of the back garment near the front of the garment.
5. The physical cooling garment with water supplementing function according to claim 4, characterized in that, The back garment has several second mounting pockets on the side near the front garment, and the physical cooling block structure is placed in the second mounting pockets.
6. The physical cooling garment with water supplementing function according to claim 1, characterized in that, The hydration structure is installed on the side of the back garment away from the front garment.
7. The physical cooling garment with water supplementing function according to claim 1, characterized in that, The back cover has a cavity with an opening at the top, and the opening is equipped with a zipper. The water-replenishing structure is placed inside the cavity.