MAN-MADE FIBER CLOTH HAVING BUOYANCY AND WARMTH

Abstract

A man-made fiber cloth having buoyancy and warmth comprises a fiber cloth and a plurality of air capsules distributedly set in the fiber cloth; wherein the fiber cloth comprises a plurality of long fibers and hot-melt collodion-cottons bonded to each other. The air capsule is a plasticized material, and the air capsule has a particle diameter of 0.1 mm to 10 mm; and at the same time, due to the plasticized material, the hot-melt collodion-cotton and the long fibers can be bonded into a one-body during the heating process. Therefore, when the man-made fiber cloth is made into a garment or an article, the thermal conductivity can be lowered due to the setting of the air capsules, so the garment is uneasy to dissipate the heat and the warmth effect is improved. The characteristic of wrapping air of the air capsule reduce the overall weight of the clothing to achieve the effects of lightness and comfort. Furthermore, when the user accidentally falls into the water, the air capsule can also provide buoyancy as a life jacket.

Claims

1. A man-made fiber cloth having buoyancy and warmth, which comprises a fiber cloth and a plurality of air capsules, wherein the air capsules are distributedly and fixedly set in the fiber cloth; wherein the fiber cloth comprises a plurality of long fibers and hot-melt collodion-cottons; in addition, the air capsule is a plasticized material, and the air capsule has a particle diameter of 0.1 mm to 10 mm; wherein the air capsules are distributed in the fiber cloth by a hot-pressing way, and are bonded and fixed to the hot-melt collodion-cottons and the long fibers with each other.

2. The man-made fiber cloth having buoyancy and warmth according to claim 1, wherein the hot-melt collodion-cottons and the air capsules can be completely mixed and blended firstly, and then formed into the man-made fiber cloth by adopting a hot-pressing way.

3. The man-made fiber cloth having buoyancy and warmth according to claim 1, wherein an accommodating space is formed inside the air capsule, and the accommodating space is in a vacuum state.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is a structural schematic diagram of a preferred embodiment of the present invention.

[0013] FIG. 2 is a using state structural schematic diagram of a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0014] The following descriptions are exemplary embodiments only, and are not intended to limit the scope, applicability or configuration of the invention in any way. Rather, the following detailed description provides a convenient illustration for implementing exemplary embodiments of the invention. Various changes to the described embodiments may be made in the function and arrangement of the elements described without departing from the scope of the invention as set forth in the appended claims.

[0015] The foregoing and other aspects, features, and utilities of the present invention will be best understood from the following detailed description of the preferred embodiments when read in conjunction with the accompanying drawings.

[0016] Please refer to FIG. 1 and FIG. 2, which are a man-made fiber cloth 3 having buoyancy and warmth of a preferred embodiment of the present invention; and which comprises a fiber cloth 31 and a plurality of air capsules 32, wherein the air capsules 32 are distributedly and fixedly set in the fiber cloth 31; wherein the fiber cloth 31 comprises a plurality of long fibers 311 and hot-melt collodion-cottons 312 bonded to each other; and the air capsules 32 are distributed in the fiber cloth 31 and are bonded and fixed on the hot-melt collodion-cottons 312 and the long fibers 311.

[0017] Continuing the foregoing description; in the actual production, the long fibers 311, the hot-melt collodion-cottons 312, and the air capsules 32 can be completely mixed and blended firstly, and then hot-pressed to form the man-made fiber cloth 3; or, making the long fibers 311 and the hot-melt collodion-cottons 312 form the fiber cloth 31 firstly, and then the fiber cloth 31 and the air capsules 32 are hot-pressed to form the man-made fiber cloth 3. Hereafter the present embodiment will use an example to explain; wherein the long fibers 311, the hot-melt collodion-cottons 312, and the air capsules 32 are completely mixed and blended firstly, and then hot-pressed to form the man-made fiber cloth 3.

[0018] Continuing the foregoing description; the hot-pressing method means that the long fibers 311 and the hot-melt collodion-cottons 312 are heated, for example, a high-temperature gas is blown into the long fibers 311 and the hot-melt collodion-cottons to heat; the long fibers 311 or the hot-melt collodion-cottons 312 are heated to be partially dissolved to produce stickiness; and then pressing the hot-melt collodion-cottons 312 and the long fibers 311 to form the fiber cloth 31; or, the hot-pressing method can be directly adopted to directly heat and press to make partial long fibers 311 or partial hot-melt collodion-cottons 312 dissolve to be bonded to a one-body; and at the same time, the air capsules 32 are adhesively fixed into the one-body, so that the man-made fiber cloth 3 can be directly manufactured to use following up for garment (clothes, pants) or articles (such as blankets, bags) and the like.

[0019] Continuing the foregoing description, the air capsules 32 is a plasticized material, which can be relatively dissolved due to the surface of the plasticized material during the heating process; so after the long fibers 311 and the hot-melt collodion-cottons 312 are dissolved, they will be bonded with the surface of the air capsules 32 to form into a one-body. Therefore, the fiber cloth 31 is bonded and solidified, and will not be displaced after forming; at the same time, the air capsules 32 has the design of wrapping air inside; wherein the air capsule 32 has formed an interior accommodating space 321 which can wrap the air or is in a vacuum state; and the air capsule 32 has an optimum particle diameter of 0.1 mm to 10 mm. Since the air capsule 32 itself is a plasticized material and is designed of wrapping air inside or being vacuum, it has a characteristic of light-weight and does not increase the weight of the fiber cloth 3; and the air capsule 32 is a micro design of 0.1 mm to 10 mm which is bonded and fixed on the long fiber 311 or the hot-melt collodion-cotton 312; it is equivalent to form a one-body design for the air capsules 32, the long fibers 311, and the hot-melt collodion-cottons 312, it won't be particularly awkward to use. Further, after the air capsule 32 is pressed, the air therein is not a solid design, so the shape of the air capsule 32 will change with pressure; therefore the tactile impression of the air capsule 32 is relatively unobvious, and it does not hinder the appearance of the garment made of the fiber cloth 31 or the tactile impression of being worn. Furthermore, in addition to the design of the air capsule 32, since the thermal conductivity of the air is extremely low, the temperature can be prevented from being dissipated; and the warmth retention of the man-made fiber cloth 3 can be effectively improved.

[0020] Continuing the foregoing description, please refer to FIG. 2, Since the man-made fiber cloth 3 has the air capsules 32 incorporated therein, they wrap a large amount of air or in a vacuum state; and therefore, when it is made into clothing or other commodities, it has a certain buoyancy; when it is worn during playing in the water but falling into the water accidentally, it can be used as a temporary buoyancy life jacket. Therefore, through the design of the man-made fiber cloth 3, due to the arrangement of the air capsules 32, it will make the subsequently made clothing or articles reduce weight under the same volume; thereby achieving being light, comfortable, and easy to wear and carry because the air capsule 32 has the characteristic of wrapping air. Moreover, the setting of the air capsules 32 can reduce the thermal conductivity, so that the heat energy is uneasy to dissipate; thereby enhancing the warmth effect; and the air capsules 32 can also provide buoyancy as a buoyancy rescue device, thereby wholly promoting the man-made fiber cloth 3 to have the effects of lightness, warmth, and buoyancy.

[0021] In summary, the man-made fiber cloth having buoyancy and warmth of the present invention comprises a fiber cloth and a plurality of air capsules distributedly and fixedly set therein; wherein the fiber cloth comprises a plurality of long fibers and hot-melt collodion-cottons bonded to each other, and the air capsule is a plasticized material, which the air capsule has a particle diameter of 0.1 mm to 10 mm; wherein the air capsules are distributed in the fiber cloth, and are bonded and fixed on the hot-melt collodion-cottons and the long fibers. Therefore, when the man-made fiber cloth is made to clothing or articles, the setting of the air capsules can reduce the thermal conductivity, so that the heat energy is uneasy to dissipate; thereby enhancing the warmth effect; furthermore, the weight of the whole clothing can be reduced because the air capsule has the characteristic of wrapping air, thereby achieving the effects of lightness and comfort. Moreover, when the user accidentally drops into the water, the air capsules can also provide buoyancy as a life jacket, so the man-made fiber cloth has certain effects in terms of warmth, lightness, having buoyancy, and comfort wearing; therefore it indeed can achieve the object of the present invention.