The present invention relates to a method for fabricating a bra structure, particularly to a method for fabricating an air-permeable, thin and lightweight bra structure.
Brassieres are the most intimate clothes for women. As the living quality has been greatly upgraded, consumers demand higher quality and comfort of brassieres. Refer to
One objective of the present invention is to provide a method for fabricating a bra structure, which is integrally and seamlessly fabricated via compression-molding a single piece of a 3D fabric substrate, such as a spacer fabric or a sandwich fabric, whereby is exempted from the complexity of the conventional bra fabricated via sewing together several pieces of fabrics, and whereby is free of seams affecting the esthetic effect, wherefore is solved the problems mentioned above.
Another objective of the present invention is to provide a method for fabricating a bra structure, which is integrally and seamlessly fabricated via compression-molding a single piece of a 3D fabric substrate, and which has the characteristics of 3D fabrics and is air-permeable, thin, lightweight, pressure-free, and comfortable, and which is seamless and conformable to breasts and has higher breast-supporting capability.
Yet another objective of the present invention is to provide a method for fabricating a bra structure, which is suitable to be exposed or worn externally for a fashion effect.
Still objective of the present invention is to provide a method for fabricating a bra structure, whose fabrication time is decreased, and whose fabrication cost is reduced.
In order to achieve the above mentioned objectives, the present invention proposes a method for fabricating a bra structure, including steps of forming an integral 3D knitted-fabric substrate, and compression-molding said integral 3D knitted-fabric substrate to form said bra structure. The bra structure includes two cups connected to each other, each having an apex area and a peripheral area, wherein each said apex is proximate centrally middle area of an associated cup of the two cups and each said peripheral is proximate laterally outer area of said associated cup, and two wings respectively extending from said peripheral areas of said two cups, wherein ends of said wings, which are far away from said cups, are configured to be fastened together. The two cups and two wings are made of said integral 3D knitted-fabric substrate, and the integral 3D knitted-fabric substrate is compressed to have a larger thickness in the apex areas than in said peripheral areas and said wings.
In one embodiment, after compression-molding, the 3D knitted-fabric substrate is gradually thinned from the apex areas to the peripheral areas. In one embodiment, after compression-molding, a thickness of the 3D knitted-fabric substrate in each the peripheral area is equal to or smaller than a thickness of the 3D fabric substrate in the associated wing. In one embodiment, after compression-molding, the 3D knitted-fabric substrate in each the wing is gradually thinned from one end of the associated wing, which is near the associated cup, to another end of the associated wing, which is far away from the associated cup.
In one embodiment, each the apex area is at a center of the associated cup and occupies 30-50% area of the cups; the 3D knitted-fabric substrate is 2 mm-10 mm thick in each the apex area, and wherein the 3D knitted-fabric substrate is 0.1 mm-5 mm thick in each the peripheral area and each the wing.
In one embodiment, the two cups are connected by a central member, and wherein the two cups, the central member and the two wings are integrally fabricated via compression-molding a single piece of the 3D knitted-fabric substrate. In one embodiment, the 3D knitted-fabric substrate is a sandwich fabric or a spacer fabric.
In one embodiment, the 3D knitted-fabric substrate includes an upper fabric layer, a lower fabric layer, and a middle fabric layer between the upper fabric layer and the lower fabric layer, and wherein the middle fabric layer is formed by several pieces of waved yarn, and wherein crests of the waved yarn are connected with the upper fabric layer, and wherein troughs of the waved yarn are connected with the lower fabric layer. In one embodiment, the waved yarn of the middle fabric layer is formed by monofilaments.
In one embodiment, either the upper fabric layer or the lower fabric layer is knitted with shrinkable core-spun yarn. Either the upper fabric layer or the lower fabric layer is knitted with polyester yarn, elastic yarn, nylon yarn, cotton yarn, rayon yarn, or a combination thereof.
In one embodiment, the method further includes a step of forming an outer covering layer stuck to an outer surface of the 3D knitted-fabric substrate. The 3D knitted-fabric substrate and the outer covering layer are jointly compression-molded to integrally form the two cups connected to each other and the two wings extended from the cups.
In one embodiment, the outer covering layer is a knitted fabric, a woven fabric, a woolen fabric, a nylon fabric, a rayon fabric, a polyester fabric, or a cotton fabric.
In one embodiment, jacquard, embossing, printing or a combination thereof is formed on at least one surface of the 3D knitted-fabric substrate. In one embodiment, bordering elements are sewed on a portion of edges of the cups and the wings, and wherein steel wires are disposed in lower edges of inner sides of the cups.
In one embodiment, the method further includes a step of forming two shoulder straps. One end of each the shoulder strap is connected with an upper edge of the associated cup, and another end of the shoulder strap is connected with an upper edge of the associated wing connected with the associated cup.
In one embodiment, ends of the two wings, which are far away from the cups, are fastened together with a hook and eye fastening mechanism, a hook and loop fastening mechanism, or an elastic ribbon.
Refer to
In one embodiment, the apex areas 321 and 321′ are respectively about at the centers of the cups 32 and 32′. Each of the apex areas 321 and 321′ occupies 30-50% area of the cup 32 or 32′. The peripheral areas 322 and 322′ respectively surround the apex areas 321 and 321′. Two cups 32 and 32′ are connected by a central member 38. The central member 38 is fabricated to have a strip-like shape, a belt-like shape, or a triangle-like shape. The cups 32 and 32′, the central member 38 and the wings 34 and 34′ are simultaneously integrally fabricated via compression-molding a single piece of the seamless 3D fabric substrate 36. In one embodiment, fastening eye positioning grooves 40 where fastening eyes will be installed are simultaneously compression-molded at one end of the wing 34′, which is far away from the cup 32′. The fastening eyes are corresponding to the hooks installed on the other wing 34. The two wings 34 and 34′ can thus be fastened together with the eyes and hooks. In one embodiment, two ends of the wings 34 and 34′, which are far away from the cups 32 and 32′, are fastened together with a hook-and-loop mechanism or an elastic ribbon.
In one embodiment, after compression-molding, the thickness of the 3D fabric substrate 36 in the cups 32 and 32′ is gradually decreased from the apex areas 321 and 321′ to the peripheral areas 322 and 322′. In one embodiment, after compression-molding, the thickness of the 3D fabric substrate 36 in the peripheral areas 322 and 322′ is equal to or smaller than the thickness of the 3D fabric substrate 36 in the wings 34 and 34′. The thickness may be evenly distributed or variable in the wings 34 and 34′. In one embodiment, after compression-molding, the thickness of the 3D fabric substrate 36 in the wing 34 (34′) is gradually decreased from one end of the wing 34 (34′), which is near the cup 32 (32′), to the other end of the wing 34 (34′), which is far away from the cup 32 (32′). In one embodiment, the 3D fabric substrate 36 is about 2 mm-10 mm thick in the apex areas 321 and 321′ and 0.1 mm-5 mm thick in the peripheral areas 322 and 322′ and the wings 34 and 34′.
In one embodiment, the 3D fabric substrate 36 includes an upper fabric layer 361, a lower fabric layer 363 and a middle fabric layer 362 between the upper fabric layer 361 and the lower fabric layer 363. The upper fabric layer 361, the middle fabric layer 362, and the lower fabric layer 363 are knitted in a 3D knitting method to form a sandwich fabric (also called the spacer fabric). In one embodiment, the middle fabric layer 362 is formed by several pieces of waved yarn, wherein the crests of the waved yarn are connected with the upper fabric layer 361, and the troughs of the waved are connected with the lower fabric layer 363. The 3D fabric substrate 36 whose middle fabric layer 362 is formed by waved yarn is favorable to air permeability. In one embodiment, the waved yarn of the middle fabric layer 362 is formed by monofilaments.
Refer to
In one embodiment, the upper fabric layer 361 and/or the lower fabric layer 362 is knitted with shrinkable core-spun yarn. The core-spun yarn of the upper fabric layer 361 and/or the lower fabric layer 362 is knitted with polyester yarn, elastic yarn, nylon yarn, cotton yarn, rayon yarn, or a combination thereof. In one embodiment, jacquard, embossing, printing or a combination thereof is formed on the upper fabric layer 361 and/or the lower fabric layer 362.
The bra structure 30, which is fabricated via compression-molding a single piece of fabric (the 3D fabric substrate), can be further fabricated to meet different requirements. Refer to
Refer to
In the present invention, only a single piece of fabric (the 3D fabric substrate) is used to fabricate the bra structure. Therefore, the present invention can simplify the fabrication process, decrease the material cost and lower the fabrication cost. Further, the bra structure of the present invention is integrally and seamlessly fabricated via compression-molding a single piece of a 3D fabric substrate. Therefore, the present invention is exempted from the complexity of the conventional bra fabricated via sewing together several pieces of fabrics and free of seams affecting the esthetic effect. Furthermore, the present invention compression-molds a single piece of fabric to integrally form the bra structure. Therefore, the present invention can save the fabrication time and further lower the fabrication cost. As the present invention compression-molds a single piece of a seamless 3D fabric substrate to integrally form the bra structure, the bra structure is air-permeable, thin, lightweight and pressure-free. Moreover, as the bra structure of the present invention is seamless, it is conformable to breasts and has better breast-supporting capability. In addition to having a simpler fabrication process, the bra structure with an outer covering layer stuck to the 3D fabric substrate can use the materials and patterns of the outer covering layer to present different visual effects. Hence, the bra structure of the present invention is suitable to be worn or exposed externally for a fashion effect.
Although the present invention has been explained in relation to its preferred embodiment, it is to be understood that other modifications and variation can be made without departing the spirit and scope of the invention as hereafter claimed.
Number | Date | Country | Kind |
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105137132 | Nov 2016 | TW | national |
This application is a division of and claims the priority benefit of U.S. patent application Ser. No. 15/361,230, filed on Nov. 25, 2016. The entirety of the above-mentioned patent applications are hereby incorporated by references herein and made a part of the specification.
Number | Date | Country | |
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Parent | 15361230 | Nov 2016 | US |
Child | 16846712 | US |