CN220464972U - Windproof cold fabric and windproof cold suit - Google Patents

Abstract

The utility model discloses a windproof and cold-resistant fabric and windproof and cold-resistant garment, which comprise an outer layer, a middle layer and an inner layer, wherein the outer layer is used for windproof and water-resistant, the middle layer is used for keeping warm, the inner layer is directly contacted with a human body, the outer layer comprises a waterproof layer and a composite layer, the waterproof layer is used for water resistance, the composite layer is matched from outside to inside, and a membrane rib part is uniformly arranged on the composite layer; 1. powerful waterproof performance: the Gore-Tex waterproof layer is adopted as a part of the outer layer fabric, so that the waterproof performance is excellent. It can effectively resist the penetration of external moisture, keep the body dry and prevent the moisture from entering the clothes. 2. Excellent warm-keeping effect: the heat locking layer is used as a part of the middle layer fabric, can absorb and store heat energy, and provides excellent heat preservation performance. It can effectively maintain body temperature and prevent heat loss, both in cold climates and in low temperature environments.

Description

Windproof cold fabric and windproof cold suit

Technical Field

The utility model relates to the technical field of cold-proof clothing, in particular to a windproof and cold-proof fabric and windproof and cold-proof clothing.

Background

Wind-cold resistant garments are garments designed to protect the body from cold, weather and bad weather conditions. It is typically constructed of multiple layers of fabric, including an outer layer of fabric, an inner layer of fabric, and an intermediate layer of fabric, each having different functions and characteristics.

(1) Outer layer fabric: the outer layer fabric is a first defense line of the windproof and coldness-proof suit and is used for resisting wind power and precipitation. It is often required to have waterproof, windproof and breathable properties.

(2) Middle layer fabric: the middle layer fabric is a warm-keeping layer of the windproof cold suit and is used for storing body heat and blocking cold air. Its main function is to provide warmth retention and breathability.

(3) Inner layer fabric: the inner layer fabric is positioned at the innermost side of the wind-cold-proof garment and is directly contacted with the skin. Its main functions are to keep comfortable and to absorb moisture and perspiration.

The fabric of the wind-cold-proof garment is selected to provide the functions of wind prevention, water prevention, heat preservation, ventilation and the like. The selection and combination of specific fabrics will likely vary depending on the environment of use, design goals, and anticipated performance requirements of the garment. But the principle is consistent.

However, through long-term work and research of the inventor, the following technical problems in the windproof cold fabric and windproof cold suit in the traditional technology need to be solved:

(1) The waterproof performance is not enough: the waterproof layer of the conventional windproof clothing fabric may have a water seepage problem, and particularly, in the case of long-term rainwater soaking or extreme weather conditions, the waterproof layer may not effectively prevent water seepage, so that the interior of the clothing is moist.

(2) The thermal insulation performance is limited: the thermal layer of conventional windshields relies primarily on heavy fabrics and padding, which may limit the breathability and flexibility of the garment and may not provide adequate thermal performance, particularly in extremely cold environments.

(3) Lack of temperature regulating function: the thermal layer of conventional windshields is generally static and cannot be automatically adjusted according to changes in ambient temperature. This means that the garment may overheat and be uncomfortable when the temperature increases, and may not provide a sufficient warming effect when the temperature decreases.

(4) The air permeability is insufficient: the conventional windproof garment fabric may sacrifice breathability while pursuing windproof performance. This results in perspiration and inability of the body to drain in time, causing discomfort and a moist feel.

Therefore, a windproof and cold-resistant fabric and windproof and cold-resistant clothing are provided.

Disclosure of Invention

In view of the above, the embodiment of the utility model hopes to provide a windproof cold fabric and windproof cold suit, which solve or alleviate the technical problems in the prior art, namely, insufficient water performance, limited heat retention, lack of temperature regulation function and insufficient air permeability, and at least provide a beneficial choice for the problems;

the technical scheme of the embodiment of the utility model is realized as follows:

first aspect

The wind and cold prevention fabric comprises a traditional mode, wherein the wind and cold prevention fabric comprises an outer layer, a middle layer and an inner layer, the outer layer is used for wind prevention and water prevention, the middle layer is used for keeping warm, the inner layer is directly contacted with a human body, the waterproof layer is used for water prevention, the composite layer is used for wind prevention, and the composite layer is matched from outside to inside, and a membrane rib part is uniformly arranged on the composite layer; the middle layer comprises a heat locking layer provided with an array heat locking part; the inner layer includes a fabric layer and a contact layer that are form-fit from the outside to the inside.

In the above embodiment, the embodiment of the wind-cold-proof fabric adopts a traditional structure of overlapping from outside to inside. The composite material comprises an outer layer, an intermediate layer and an inner layer. The outer layer is composed of a waterproof layer and a windproof composite layer, the waterproof layer is used for preventing moisture from penetrating, and the windproof composite layer is used for blocking wind power. The intermediate layer includes a heat blocking layer having heat blocking portions in an array. The inner layer consists of a fabric layer and a contact layer, and the contact layer is directly contacted with a human body.

Wherein in one embodiment: the waterproof layer is a nylon waterproof layer, a polyester fiber waterproof layer or a Gore-Tex waterproof layer.

In the above embodiment, the waterproof layer may be a nylon waterproof layer, a polyester fiber waterproof layer, or a goldner (Gore-Tex) waterproof layer. The choice of these waterproof layers depends on the design requirements and the desired properties of the product.

Wherein in one embodiment: the waterproof layer is preferably a Gore-Tex waterproof layer.

In the above embodiment, a Goldener (Gore-Tex) waterproof layer is preferably selected as the waterproof layer. The Gore-Tex waterproof layer is preferably selected as the waterproof layer, so that the wind-cold-resistant fabric is provided with excellent waterproof air permeability, and the requirements of outdoor activities and severe weather environments are met.

Wherein in one embodiment: the composite layer is preferably a Wen Taier (ventille) composite layer. The membrane rib parts are uniformly arranged on the composite layer in a rectangular array mode, and the membrane rib parts uniformly divide the composite layer into block-shaped areas.

In the above embodiment, wen Taier (vent) composite layer is selected as the composite layer. Rectangular array membrane rib parts are uniformly arranged on the composite layer, and the membrane rib parts uniformly divide the composite layer into block-shaped areas. Wen Taier (ventille) composite layer provides excellent windproof and waterproof properties for the windproof and waterproof fabric. The structural stability of the composite layer and the design of the membrane rib portion enable the fabric to provide reliable windproof protection in severe environments while maintaining interior dryness and comfort.

Wherein in one embodiment: the waterproof layer and the composite layer are connected by thermal bonding, pressing, gluing or stitching.

In the above embodiment, the waterproof layer and the composite layer are connected by thermal bonding, press bonding, glue bonding or stitching. The connection modes can ensure the tight combination between the waterproof layer and the composite layer so as to enhance the overall performance of the fabric. The waterproof layer and the composite layer are connected by thermal adhesion, press fit, glue or stitching to ensure firm connection and excellent performance. The connecting mode is a common method in fabric manufacturing, can provide reliable waterproof and windproof performance, and ensures the durability and the comfort of the fabric.

Wherein in one embodiment: the heat locking part of the heat locking layer is honeycomb-shaped.

In the above embodiment, the heat locking portion of the heat locking layer is designed in a honeycomb shape. The honeycomb-shaped heat-locking portion exhibits a hexagonal or honeycomb-like structure on the heat-locking layer. The heat-locking portion of the heat-locking layer adopts a honeycomb-shaped design, and provides excellent heat-insulating effect by forming small air compartments. The honeycomb structure can effectively prevent heat conduction, keep the inside warm, and enable the wind-cold-proof suit to have excellent warm keeping function in a cold environment.

Wherein in one embodiment: the heat locking layer is preferably one of a PCM heat locking layer, a silver fiber heat locking layer, a carbon fiber heat locking layer or a ceramic fiber heat locking layer.

In the above embodiments, the preferred choice of the heat locking layer includes one of PCM (phase change material) heat locking layer, silver fiber heat locking layer, carbon fiber heat locking layer or ceramic fiber heat locking layer. These materials are used as the primary component of the heat blocking layer to provide excellent thermal protection. The heat-locking layer materials are selected to enhance the heat-insulating capability of the wind-cold-proof suit, so that the heat-locking layer materials can provide better heat-insulating effect in a low-temperature environment. Different heat-blocking layer materials have different characteristics and can be selected according to specific requirements and use environments so as to provide optimal heat-insulating performance.

Wherein in one embodiment: the fabric layer and the contact layer are thermally bonded, press-fit, glued or stitched. The fabric layer is a cashmere fabric layer, and the contact layer is a cotton layer.

In the above embodiments, the fabric layer and the contact layer are connected by means of a thermal adhesive connection, a press connection, a glue connection or a stitching connection. The fabric layer adopts a cashmere fabric layer as an outer layer fabric, and the contact layer adopts a cotton layer as an inner layer fabric which is directly contacted with a human body. Through thermal bonding connection, press fit connection, glued connection or stitching connection, firm connection is formed between the fabric layer and the contact layer, and the integrity and durability of the fabric are ensured. This combination provides the warmth retention, breathability and comfort required for wind-cold resistant garments, keeping the wearer warm and comfortable in cold environments.

Second aspect

The outer layer, the middle layer and the inner layer of the windproof and cold-resistant fabric are sequentially connected from outside to inside, and are connected in a bonding mode, a pressing mode, a gluing mode or a stitching mode to form a laminated material piece. The windproof and coldproof garment is formed by making a coat, a collar, sleeves, cuffs, a front part, a pocket, a hood and a lower hem through a laminated material piece.

In the above embodiment, the outer layer, the middle layer and the inner layer of the wind and cold resistant fabric are sequentially formed into the laminated material piece from outside to inside by adopting a thermal bonding connection, a pressing connection, a gluing connection or a stitching connection. The laminated material pieces can be used for manufacturing parts such as jackets, collars, sleeves, cuffs, front flaps, pockets, hoods, and pendulums of wind-cold resistant clothing.

Compared with the prior art, the utility model has the beneficial effects that:

1. powerful waterproof performance: the Gore-Tex waterproof layer is adopted as a part of the outer layer fabric, so that the waterproof performance is excellent. It can effectively resist the penetration of external moisture, keep the body dry and prevent the moisture from entering the clothes.

2. Excellent warm-keeping effect: the heat locking layer is used as a part of the middle layer fabric, can absorb and store heat energy, and provides excellent heat preservation performance. It can effectively maintain body temperature and prevent heat loss, both in cold climates and in low temperature environments.

3. Temperature regulation function: the honeycomb design of the heat-blocking layer provides a larger surface area and heat exchange area for more effective body temperature regulation. The device can absorb or release stored heat energy according to the change of external temperature, and ensure that the body keeps proper temperature under different environmental conditions.

4. Excellent air permeability: by accurate fabric connection and selection of materials with high air permeability, free circulation of air and moisture is ensured. This helps the body to sweat and moisture emissions, keeping the interior of the garment dry and comfortable.

5. Light and comfortable: the weight and thickness of the fabric are reduced by adopting light materials such as a Venturi (Ventile) composite layer and the like, and the lighter and thinner windproof and coldproof fabric is provided. This increases the comfort of wear and freedom of movement, making it more convenient and flexible in outdoor activities.

6. High quality and durability: the materials and the connection mode adopted have excellent quality and durability and can withstand various environmental and use conditions. This ensures long-term use of the wind-cold resistant garment and provides durable wind-resistance, water-resistance and warmth retention properties.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required in the embodiments or the technical descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic illustration of the wind-resistant garment and fabric composition of the present utility model;

FIG. 2 is a schematic perspective view of a laminate of the present utility model;

FIG. 3 is a schematic perspective view of a laminate of the present utility model;

FIG. 4 is a schematic perspective view of the outer layer of the present utility model;

FIG. 5 is a schematic perspective view of the outer layer of the present utility model;

FIG. 6 is a schematic perspective view of an intermediate layer of the present utility model;

fig. 7 is a schematic perspective view of an inner layer of the present utility model.

Reference numerals: 1. stacking the material pieces; 10. an outer layer; 101. a waterproof layer; 102. a composite layer; 1021. a membrane rib portion; 11. an intermediate layer; 111. locking a thermal layer; 12. an inner layer; 121. a fabric layer; 122. and a contact layer.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. This utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the utility model, whereby the utility model is not limited to the specific embodiments disclosed below;

it should be noted that the terms "first," "second," "symmetric," "array," and the like are used merely for distinguishing between description and location descriptions, and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of features indicated. Thus, a feature defining "first," "symmetry," or the like, may explicitly or implicitly include one or more such feature; also, where certain features are not limited in number by words such as "two," "three," etc., it should be noted that the feature likewise pertains to the explicit or implicit inclusion of one or more feature quantities;

in the present utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature; meanwhile, all axial descriptions such as X-axis, Y-axis, Z-axis, one end of X-axis, the other end of Y-axis, or the other end of Z-axis are based on a cartesian coordinate system.

In the present utility model, unless explicitly specified and limited otherwise, terms such as "mounted," "connected," "secured," and the like are to be construed broadly; for example, the connection can be fixed connection, detachable connection or integrated molding; the connection may be mechanical, direct, welded, indirect via an intermediate medium, internal communication between two elements, or interaction between two elements. The specific meaning of the terms described above in the present utility model will be understood by those skilled in the art from the specification and drawings in combination with specific cases.

In the prior art, the water performance is insufficient, the heat preservation performance is limited, the temperature regulation function is lacked, and the air permeability is insufficient; for this reason, referring to fig. 1-7, the present embodiment provides a related technical solution to solve the above technical problems: the wind and cold prevention fabric comprises a traditional mode of externally-overlapped wind and water prevention outer layer 10, a warm middle layer 11 and an inner layer 12 which are directly contacted with a human body, wherein the outer layer 10 comprises a water prevention layer 101 and a wind prevention composite layer 102 which are matched from outside to inside, and a membrane rib part 1021 is uniformly arranged on the composite layer 102; the intermediate layer 11 includes a heat locking layer 111 provided with heat locking portions in an array form; the inner layer 12 includes a fabric layer 121 and a contact layer 122 that are form-fitted from the outside to the inside.

In the scheme, the implementation mode of the wind and cold prevention fabric adopts a traditional structure of overlapping from outside to inside. Specifically comprises an outer layer 10, an intermediate layer 11 and an inner layer 12. The outer layer 10 is composed of a waterproof layer 101 for preventing moisture penetration and a wind-proof composite layer 102 for blocking wind power. The intermediate layer 11 includes a heat blocking layer 111, and the heat blocking layer 111 has heat blocking portions in an array form. The inner layer 12 is composed of a fabric layer 121 and a contact layer 122, the contact layer 122 being in direct contact with the human body.

Specifically, the design principle of the windproof and cold-proof fabric is that through the combination of the multi-layer fabrics, each layer of fabric plays different functions, so that windproof, waterproof and warm-keeping effects are provided. The waterproof layer 101 of the outer layer 10 can effectively prevent moisture penetration and prevent external rainwater from penetrating. The wind-proof composite layer 102 can block the invasion of wind power and reduce the influence of cold wind on the body. The heat-locking layer 111 of the intermediate layer 11 can effectively store body heat through the heat-locking parts in the form of an array, and provides additional heat-insulating performance. The fabric layer 121 of the inner layer 12 provides a comfortable, snug feel, while the contact layer 122 directly contacts the human body, with a comfortable feel.

It will be appreciated that in this embodiment, the wind and cold resistant fabric has multiple protections in functionality. The waterproof layer 101 of the outer layer 10 is able to resist rain and moisture, keeping the body dry. The wind-proof composite layer 102 effectively blocks cold wind, reduces heat dissipation, and maintains body temperature. The heat locking layer 111 provides an additional warm keeping effect through the design of the heat locking part, and effectively blocks cold air from entering the body. The fabric layer 121 and the contact layer 122 of the inner layer 12 provide a comfortable, intimate feel and contact with the skin, helping to regulate humidity and breathability and improving overall comfort. In a comprehensive view, the windproof and cold-proof fabric can provide good windproof, waterproof and warm-keeping functions for users, so that the windproof and cold-proof fabric is comfortable and warm under severe weather conditions.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the waterproof layer 101 is a nylon waterproof layer 101, a polyester fiber waterproof layer 101 or a goldner (Gore-Tex) waterproof layer 101.

In this embodiment, the waterproof layer 101 may be a nylon waterproof layer 101, a polyester waterproof layer 101 or a goldner (Gore-Tex) waterproof layer 101. The choice of these waterproof layers 101 depends on the design requirements and the desired properties of the product.

Specifically, the nylon waterproof layer 101, the polyester fiber waterproof layer 101, and the goldner (Gore-Tex) waterproof layer 101 all have excellent waterproof properties. They are made using different techniques and materials to ensure that the waterproof layer 101 is able to effectively block moisture penetration. These waterproof layers 101 are formed into a tight structure using special coating, film or textile techniques, thereby preventing moisture penetration through the fabric pores or interstices between the fibers. They provide a reliable waterproof barrier on the outermost side of the outer layer 10 facing, protecting the inner layer from intrusion of rain and moisture.

It is understood that in the present embodiment, the nylon waterproof layer 101, the polyester fiber waterproof layer 101 and the goldner (Gore-Tex) waterproof layer 101 all have excellent waterproof performance, and can provide reliable waterproof protection under severe weather conditions. They are effective against rain, snow and moisture, keeping the body dry and comfortable. The choice of waterproof layer 101 will be determined by the specific requirements. The nylon waterproof layer 101 has excellent wear resistance and portability, and is suitable for applications requiring high durability and flexibility. The polyester fiber waterproof layer 101 has good waterproof performance and air permeability, and is suitable for application scenes requiring good air permeability. The Gore-Tex waterproof layer 101 adopts a unique waterproof breathable film technology, can realize high balance of waterproof performance and breathable performance, and is suitable for application with high requirements on waterproof performance and breathable performance.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the waterproof layer 101 is preferably a Goldener (Gore-Tex) waterproof layer 101.

In this embodiment, a Goldener (Gore-Tex) waterproof layer 101 is preferably selected as the waterproof layer 101. The goldner (Gore-Tex) waterproof layer 101 is preferably selected as an embodiment of the waterproof layer 101, which provides excellent waterproof and breathable properties for the wind and cold resistant fabric, and meets the requirements of outdoor activities and severe weather environments.

Specifically, the Goldener (Gore-Tex) waterproof layer 101 employs a unique membrane layer structure. The membrane layer is made of a special polymer material and contains hundreds of millions of micropores. These micropores are small enough to block the penetration of liquid moisture, but large enough to allow the removal of water vapor from the interior. This structure provides the Gore-Tex waterproof layer 101 with excellent waterproof and breathable properties. When the fabric is exposed to external moisture, the micropores of the waterproof layer 101 prevent the moisture from entering the inside of the fabric, and keep the inside dry. At the same time, through the micropores of the waterproof layer 101, body heat and moisture can penetrate from the inside, so that moisture can be discharged, and comfort can be maintained.

It is understood that, in the present embodiment, the goldner (Gore-Tex) waterproof layer 101 is selected as the embodiment of the waterproof layer 101, and excellent waterproof and breathable properties are imparted to the weather resistant fabric. The microporous membrane structure of the goldner-Tex waterproof layer 101 can effectively prevent infiltration of rainwater and snow water while allowing body heat and moisture to be discharged through the fabric, keeping the interior dry and comfortable. The waterproof air permeability enables the fabric to be suitable for activities under various outdoor exercises and severe weather conditions, and reliable waterproof protection and comfort are provided.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the composite layer 102 is preferably a Wen Taier (vent) composite layer 102. The composite layer 102 is uniformly provided with the membrane rib sections 1021 in a rectangular array, and the membrane rib sections 1021 uniformly divide the composite layer 102 into block-shaped areas.

In this scenario, wen Taier (vent) composite layer 102 is selected as composite layer 102. Rectangular arrays of membrane tendon sections 1021 are uniformly provided on the composite layer 102, and these membrane tendon sections 1021 divide the composite layer 102 uniformly into block-shaped regions. Wen Taier (ventille) composite layer 102 provides excellent windproof and waterproof properties to the windproof and waterproof fabric as an embodiment of composite layer 102. The structural stability of the composite layer 102 and the design of the membrane tendon 1021 enable the fabric to provide reliable wind protection in harsh environments while maintaining interior dryness and comfort.

Specifically, wen Taier (vent) composite layer 102 is a high performance windproof material. It adopts special composite technology to combine the waterproof layer 101 and the windproof layer to form a composite layer 102. The structure of this composite layer 102 has excellent properties in both windbreak and water resistance. The presence of the membrane tendon 1021 further enhances the structural stability and wind resistance of the composite layer 102.

Further, structural stability is enhanced: the membrane rib 1021 is a rectangular array formed uniformly on the composite layer 102, and divides the composite layer 102 into block-shaped regions. The design can effectively increase the surface tension of the fabric and provide better structural support when the fabric is subjected to external wind force. The existence of the membrane rib parts 1021 makes the composite layer 102 stronger and not easy to deform, and keeps a stable shape, thereby enhancing the structural stability of the fabric.

The windproof performance is improved: the membrane rib parts 1021 form a series of tiny bulges on the surface of the fabric to form tiny resistance, so that the penetration of the wind can be effectively prevented. The design reduces the impact and penetration of external wind force to the fabric, reduces wind-cold feeling and improves the windproof performance. The membrane rib parts 1021 are uniformly distributed and in a rectangular array form, so that the whole fabric can be subjected to balanced wind resistance, and the wind prevention effect is further enhanced.

It will be appreciated that in this embodiment, wen Taier (ventille) composite layer 102 is selected as an embodiment of composite layer 102 to provide excellent wind and water resistance to wind and cold resistant fabrics. Wen Taier (ventille) composite layer 102 organically combines the waterproof layer 101 and the windproof layer together by a composite technique to form a tight and stable structure. This structure effectively blocks the penetration of external wind and moisture, keeping the interior comfortable and dry. The existence of the membrane rib parts 1021 further increases the stability and wind resistance of the composite layer 102, so that the fabric can better keep the wind-proof effect in a strong wind environment.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the waterproof layer 101 and the composite layer 102 are thermally bonded, press-fit, glued or stitched.

In this embodiment, the waterproof layer 101 and the composite layer 102 are connected by thermal bonding, press bonding, gluing or stitching. These connection means can ensure tight bonding between the waterproof layer 101 and the composite layer 102 to enhance the overall performance of the fabric. The waterproof layer 101 and the composite layer 102 are bonded by thermal bonding, press bonding, glue bonding or stitching to ensure a firm bond and excellent performance. The connecting mode is a common method in fabric manufacturing, can provide reliable waterproof and windproof performance, and ensures the durability and the comfort of the fabric.

Specifically, the thermal bonding connection is to fuse the materials between the waterproof layer 101 and the composite layer 102 together by heat to form a strong connection. The bonding is to apply high pressure to bond the waterproof layer 101 and the composite layer 102 together. The glued joint uses a special adhesive to bond the waterproof layer 101 and the composite layer 102 together to form a durable joint. The stitching is to sew the waterproof layer 101 and the composite layer 102 together by sewing thread to ensure that they are tightly combined.

It will be appreciated that in this embodiment, a good connection effect can be achieved by thermally bonding, press-fitting, glue-bonding or stitching between the waterproof layer 101 and the composite layer 102. This connection ensures the tightness and strength between the waterproof layer 101 and the composite layer 102, preventing moisture from penetrating into the interior of the fabric. Meanwhile, the firmness of connection ensures the durability and reliability of the fabric, so that the fabric can withstand long-time use and various environmental conditions.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the heat locking portion of the heat locking layer 111 has a honeycomb shape.

In this embodiment, the heat locking portion of the heat locking layer 111 is honeycomb-shaped. The honeycomb-shaped heat locking part exhibits a hexagonal or honeycomb-like structure on the heat locking layer 111. The heat locking portion of the heat locking layer 111 is designed in a honeycomb shape to provide excellent heat insulation by forming a small air compartment. The honeycomb structure can effectively prevent heat conduction, keep the inside warm, and enable the wind-cold-proof suit to have excellent warm keeping function in a cold environment.

Specifically, the honeycomb-shaped heat locking part design has excellent heat preservation performance. The honeycomb structure is made up of a plurality of hexagonal cells that form a unique air layer. Air as a thermal insulation medium can effectively block heat conduction. Therefore, the honeycomb shape of the heat locking part can form a plurality of small air compartments in the heat locking layer 111, effectively reducing heat transfer, and providing good heat insulation effect.

It will be appreciated that in this embodiment, the heat-blocking layer 111 provides excellent thermal insulation using a honeycomb-shaped heat-blocking portion design. The small air compartments in the honeycomb structure effectively slow down the conduction of heat, form a thermal insulation layer, block the invasion of outside cold air and keep the interior warm. The design ensures that the windproof cold suit can effectively lock body heat in a low-temperature environment and provides comfortable warm-keeping experience for a wearer.

In some embodiments of the present application, please refer to fig. 2-7 in combination: the heat locking layer 111 is preferably one of a PCM heat locking layer 111, a silver fiber heat locking layer 111, a carbon fiber heat locking layer 111 or a ceramic fiber heat locking layer 111.

In this embodiment, the preferred choice of the heat-locking layer 111 includes one of a PCM (phase change material) heat-locking layer 111, a silver fiber heat-locking layer 111, a carbon fiber heat-locking layer 111 or a ceramic fiber heat-locking layer 111. These materials are used as the main component of the heat blocking layer 111 to provide excellent heat protection. The purpose of these heat-locking layer 111 materials is to enhance the heat-retaining ability of the wind-cold resistant suit so that it can provide a better heat-retaining effect in a low temperature environment. Different materials of the heat blocking layer 111 have different characteristics and can be selected according to specific requirements and use environments to provide optimal heat preservation performance.

In particular, the method comprises the steps of,

(1) PCM lock thermal layer 111: phase change materials have the property of absorbing and releasing heat in a specific temperature range. The PCM heat locking layer 111 can absorb and release heat when the temperature changes, effectively adjusting the temperature and providing a thermal insulation effect.

(2) Silver fiber heat locking layer 111: the silver fiber has good heat conductivity and electric conductivity, can rapidly transfer body heat, and provides excellent warm-keeping effect.

(3) Carbon fiber heat locking layer 111: the carbon fiber has good heat conduction performance, can rapidly conduct heat and keep the body temperature stable.

(4) Ceramic fiber heat locking layer 111: the ceramic fiber has good insulation performance and thermal stability, and can effectively isolate external cold air and keep the interior warm.

It will be appreciated that in this embodiment, the combination of the preferred materials for the heat-blocking layer 111 provides additional thermal insulation properties to the weather suit. The PCM heat-locking layer 111 may absorb or release heat according to changes in ambient temperature, regulating body temperature. The silver fiber heat-locking layer 111 and the carbon fiber heat-locking layer 111 have excellent heat conduction properties, and can rapidly transfer body heat and keep warm. The ceramic fiber heat-blocking layer 111 provides good heat-blocking properties against the invasion of external cold air.

In some embodiments of the present application, please refer to fig. 2-7 in combination: a thermal adhesive, press fit, glue or stitch bond between the fabric layer 121 and the contact layer 122. The fabric layer 121 is a cashmere fabric layer 121, and the contact layer 122 is a cotton layer.

In this embodiment, the fabric layer 121 and the contact layer 122 are connected by thermal bonding, press-fit, glue or stitching. The fabric layer 121 adopts a cashmere fabric layer 121 as the outer layer 10 fabric, and the contact layer 122 adopts a cotton layer as the inner layer 12 fabric which is in direct contact with the human body. The fabric layer 121 and the contact layer 122 form a firm connection by thermal bonding, press bonding, glue bonding or stitching, ensuring the integrity and durability of the fabric. This combination provides the warmth retention, breathability and comfort required for wind-cold resistant garments, keeping the wearer warm and comfortable in cold environments.

In particular, the method comprises the steps of,

(1) Thermal bonding connection: the fibrous material between the fabric layer 121 and the contact layer 122 is partially fused by a heat treatment to form a firm connection. The thermal adhesive connection can provide higher strength and durability.

(2) And (3) press fit connection: the fabric layer 121 and the contact layer 122 are pressed together using pressure to bond the fibers to each other to form a connection. The press fit connection may provide better bond strength and flatness.

(3) And (3) gluing and connecting: a suitable adhesive is applied between the fabric layer 121 and the contact layer 122, which are then bonded together by hot pressing or chemical reaction. The glued connection may provide a firm and reliable connection.

(4) Stitching connection: the connection is made by sewing the fabric layer 121 and the contact layer 122 with a sewing machine. The stitched connection provides a strong connection and has good flexibility and durability.

It will be appreciated that in this embodiment, the cashmere fabric layer 121 is used as the fabric layer 121, which has good warmth retention property and soft and comfortable touch, and can provide a warm and comfortable wearing experience. And the cotton layer is adopted as the contact layer 122, so that the moisture absorption, air permeability and skin affinity are good, comfortable skin touch can be kept, and sweat and moisture can be effectively absorbed.

Further, the present embodiment further provides a wind-cold-preventing fabric and wind-cold-preventing garment, referring to fig. 1, the wind-cold-preventing fabric is an outer layer 10, an intermediate layer 11 and an inner layer 12, and the outer layer 10, the intermediate layer 11 and the inner layer 12 are sequentially connected from outside to inside by bonding, pressing, gluing or stitching to form the laminated material 1. The wind-cold-proof suit is made into a coat, a collar, sleeves, cuffs, a front part, a pocket, a hood and a lower hem through the laminated material piece 1, and the wind-cold-proof suit is formed.

In this scheme, the outer layer 10, the middle layer 11 and the inner layer 12 of the wind and cold resistant fabric are sequentially connected from outside to inside by thermal bonding, pressing, gluing or stitching to form the laminated material 1. These laminates 1 can be used to make parts such as jackets, collars, sleeves, cuffs, flaps, pockets, hoods, and shirts of wind-cold resistant garments.

Specifically, a thermal adhesive connection, a press fit connection, a glue connection or a stitch connection: the outer layer 10 facing 10, the intermediate layer 11 facing 11, and the inner layer 12 facing 12 are sequentially joined together by suitable heat, pressure, or adhesive means, to form the laminate 1. This means of attachment ensures a secure connection and integrity between the layers of fabric.

It will be appreciated that in this embodiment, the various parts of the wind-cold resistant garment may be made by sequentially joining the outer layer 10, intermediate layer 11 and inner layer 12 panels into the laminate 1. This configuration can provide multiple protection and functions:

(1) The outer layer 10 is made of a material with good waterproof and windproof performances, so that wind and rain and outside cold air can be effectively blocked, and the body can be kept dry and warm.

(2) The middle layer 11 is made of a material having a heat locking function, such as a PCM heat locking layer 111, a silver fiber heat locking layer 111, a carbon fiber heat locking layer 111, or a ceramic fiber heat locking layer 111. These materials are capable of absorbing and storing heat and releasing thermal energy when needed, providing additional thermal insulation.

(3) The inner layer 12 is made of soft and skin-friendly materials, such as cotton layers, so that the garment is comfortable and soft when contacting with skin, has the characteristics of moisture absorption and ventilation, and keeps the body dry and comfortable.

The windproof and cold-proof garment made of the laminated material piece 1 can provide omnibearing protection and warm-keeping functions, effectively block wind-cold, keep the body warm and keep comfortable wearing sense. The connection mode of each part ensures the firm structure and high durability of the garment. The design and the structure enable the wind-cold-proof suit to provide reliable protection in cold environments, and be suitable for outdoor activities and use under extreme climatic conditions.

Summarizing, aiming at the related problems in the prior art, the specific embodiment is based on the windproof and cold-resistant fabric and windproof and cold-resistant clothing, and adopts the following technical means or characteristics to realize solving:

1. improvement of waterproof performance: a goldner (Gore-Tex) waterproof layer 101 is used as a part of the outer layer 10 fabric, and the waterproof layer 101 has excellent waterproof performance. The waterproof and breathable clothing has the advantages that through the special structure of the microporous membrane, waterproof and breathable properties are achieved, and moisture is effectively prevented from penetrating into the clothing.

2. Improvement of heat preservation performance: the heat locking layer 111 is used as a part of the fabric of the middle layer 11, and comprises a PCM heat locking layer 111, a silver fiber heat locking layer 111, a carbon fiber heat locking layer 111 or a ceramic fiber heat locking layer 111. These heat blocking layers 111 have high thermal capacity and conductivity, and can absorb and store heat energy and release the heat energy when needed, thereby providing better heat preservation effect.

3. Realization of temperature adjusting function: the honeycomb design of the heat blocking layer 111 provides a larger surface area and heat exchange area that allows for more efficient temperature regulation. When the temperature rises, the heat-locking layer 111 absorbs heat and keeps the temperature proper; when the temperature drops, it releases stored thermal energy, providing additional thermal effects.

4. Promote the gas permeability: the connection between the fabric layers is ensured to be tight and smooth by means of thermal bonding connection, pressing connection, gluing connection or stitching connection, and barriers for blocking air and moisture circulation are reduced. Meanwhile, advanced fabrics and technologies are comprehensively utilized, better air permeability is provided, perspiration and moisture of a body can be discharged in time, and the body is kept dry and comfortable.

5. Weight and thickness are reduced: wen Taier (ventille) composite layer 102 as part of composite layer 102, by virtue of its lightweight and high performance characteristics, reduces the overall weight and thickness of the fabric, provides a lighter weight wind and cold resistant fabric, and increases wear comfort and freedom of movement.

The technical features of the above-described embodiments may be combined in any manner, and for brevity, all of the possible combinations of the technical features of the above-described embodiments may not be described, however, they should be considered as the scope of the present description as long as there is no contradiction between the combinations of the technical features.

Claims (10)

1. The utility model provides a cold-proof surface fabric of preventing wind, includes from outside to interior superimposed be used for preventing wind and waterproof skin (10), be used for cold-proof intermediate level (11) and direct with human contact inlayer (12), its characterized in that: the outer layer (10) comprises a waterproof layer (101) for waterproof and a composite layer (102) for windproof, which are matched from outside to inside, wherein a membrane tendon part (1021) is uniformly arranged on the composite layer (102);

the middle layer (11) comprises a heat locking layer (111) provided with array heat locking parts;

the inner layer (12) comprises a textile layer (121) and a contact layer (122) which are form-fitted from the outside to the inside.

2. The wind and cold resistant fabric of claim 1, wherein:

the waterproof layer (101) is a nylon waterproof layer, a polyester fiber waterproof layer or a Goldener waterproof layer.

3. The wind and cold resistant fabric of claim 2, wherein: the waterproof layer (101) is a Goldener waterproof layer.

4. The wind and cold resistant fabric of claim 2, wherein: the composite layer (102) is a Wentail composite layer;

the membrane rib parts (1021) are uniformly arranged on the composite layer (102) in a rectangular array mode, and the membrane rib parts (1021) uniformly divide the composite layer (102) into block-shaped areas.

5. The wind and cold resistant fabric of claim 4, wherein: and the waterproof layer (101) and the composite layer (102) are connected by thermal adhesion, press fit, gluing or stitching.

6. The wind-cold resistant fabric according to any one of claims 1 to 5, wherein: the heat locking portion of the heat locking layer (111) is honeycomb-shaped.

7. The wind and cold resistant fabric of claim 6, wherein: the heat locking layer (111) is one of a PCM heat locking layer, a silver fiber heat locking layer, a carbon fiber heat locking layer or a ceramic fiber heat locking layer.

8. The wind and cold resistant fabric of claim 1, wherein: -a thermal adhesive, press, glue or stitch connection between the fabric layer (121) and the contact layer (122).

The fabric layer (121) is a cashmere fabric layer, and the contact layer (122) is a cotton layer.

9. A windproof and cold-resistant fabric and windproof and cold-resistant garment are characterized in that: the outer layer (10), the middle layer (11) and the inner layer (12) of the wind-cold resistant fabric according to any one of claims 1 to 8 are adopted, and the outer layer (10), the middle layer (11) and the inner layer (12) are sequentially connected from outside to inside by bonding, pressing, gluing or stitching to form the laminated material (1).

10. The wind-cold resistant garment of claim 9, wherein: the windproof and coldproof garment is formed by manufacturing a coat, a collar, sleeves, cuffs, a front part, a pocket, a hood and a lower hem through a laminated material piece (1).