Abstract: An electrospinning apparatus is described. The electrospinning apparatus has a rotary nozzle mechanism that moves simultaneously along a non-linear track for forming polymeric fibrils, so that the polymeric fibrils can be piled to form a uniform web on a receiving carrier from any receiving angle. Therefore, the electrospinning apparatus resolves problems of the prior polymeric fibrils, such as various distribution and slow production rate. In addition, a method of manufacturing polymeric fibrils in the aforementioned electrospinning apparatus is further described.

Abstract: An electrospinning apparatus is described. The electrospinning apparatus has a rotary nozzle mechanism that moves simultaneously along a non-linear track for forming polymeric fibrils, so that the polymeric fibrils can be piled to form a uniform web on a receiving carrier from any receiving angle. Therefore, the electrospinning apparatus resolves problems of the prior polymeric fibrils, such as various distribution and slow production rate. In addition, a method of manufacturing polymeric fibrils in the aforementioned electrospinning apparatus is further described.

Abstract: An electrospinning apparatus is described. The electrospinning apparatus has a rotary nozzle mechanism that moves simultaneously along a non-linear track for forming polymeric fibrils, so that the polymeric fibrils can be piled to form a uniform web on a receiving carrier from any receiving angle. Therefore, the electrospinning apparatus resolves problems of the prior polymeric fibrils, such as various distribution and slow production rate. In addition, a method of manufacturing polymeric fibrils in the aforementioned electrospinning apparatus is further described.

Abstract: A face mask structure has an upper mask portion, a middle mask portion, and a lower mask portion, which are formed integrally. The upper mask portion has an upper metal stripe disposed at a proper position thereof. The lower mask portion has a lower metal stripe disposed at a proper position thereof. The upper and lower mask portions are folded in opposite directions. When in use, the upper and lower mask portions are spread out to support the middle mask portion. In this way, the face mask structure becomes fitting in with the shapes of human faces. Furthermore, the middle mask portion has multiple folding portions. When in use, the folding portions are stretched out to increase filtering area. Thereby, the inner space of the face mask structure is increased, the air-invasion rate is reduced, and the filtering efficiency is thus improved.

Abstract: The present invention relates to a method for making a micro-porous non-woven fabric, which comprises melt-blown fibers, functional particulates and low-melting point fibers. The low-melting point fibers are used to increase porosity of the non-woven fabric to enhance air permeability. The melt-blown fibers are tacky to improve the strength of adhesion between the melt-blown fibers and the functional particulates.

Abstract: A face mask structure has an upper mask portion, a middle mask portion, and a lower mask portion, which are formed integrally. The upper mask portion has an upper metal stripe disposed at a proper position thereof. The lower mask portion has a lower metal stripe disposed at a proper position thereof. The upper and lower mask portions are folded in opposite directions. When in use, the upper and lower mask portions are spread out to support the middle mask portion. In this way, the face mask structure becomes fitting in with the shapes of human faces. Furthermore, the middle mask portion has multiple folding portions. When in use, the folding portions are stretched out to increase filtering area. Thereby, the inner space of the face mask structure is increased, the air-invasion rate is reduced, and the filtering efficiency is thus improved.

Abstract: A method for forming a three-dimensional carbonizable fabric structure is provided. The fabric structure may be treated by a thermal treatment through a continuous thermal system including agent impregnation, oxidation, carbonization, and activation processes. In one embodiment the three-dimensional fabric structures are transferred through a thermal system by a tension-roller apparatus. The processing parameters includes processing temperature; processing time; addition of nitrogen, oxygen, and steam; and transferring speed, may be adjusted in accordance with the desired specific surface area, the pore size distribution, and the unit weight of the fabric structure.

Abstract: An electrospinning apparatus is described. The electrospinning apparatus has a rotary nozzle mechanism that moves simultaneously along a non-linear track for forming polymeric fibrils, so that the polymeric fibrils can be piled to form a uniform web on a receiving carrier from any receiving angle. Therefore, the electrospinning apparatus resolves problems of the prior polymeric fibrils, such as various distribution and slow production rate. In addition, a method of manufacturing polymeric fibrils in the aforementioned electrospinning apparatus is further described.

Abstract: A photocatalytic fabric products and a manufacturing method thereof uses a plasma polymerization process and a sputtering process under the vacuum environment. The protective layer is deposited on the surface of the fabric product. Then, it uses the sputtering process to excite the photocatalytic material. The atom of the photocatalytic material is excited and forms the photocatalytic thin-film on the surface of the fabric substrate. The thin-film has hydrophilic and anti-bacterial properties thereto can enhance the hydrophilic and anti-bacterial functions in the fabric product. Further, it can widely apply to the medical, upholstery, and other fiber-related field.

Abstract: The present invention refers to a metalized fiber structure and its manufacturing method. It includes a metal composite to produce high electricity, heat and other related metallic functions; a fiber structure, indicating a cubic textile fabric, to provide with the main structure strength, pattern and better space, above all, to produce higher vibration absorption, buffer, breathing, warm-maintenance, grind lasting and strengthened metallized spatial effect such as electrical capacity, electromagnetic conductivity, attachment and multi-electromagnetism block; a method to attach a metal composite to a fiber structure, featuring the way to form metal particles in a vacuum lab through stimulation of certain forces, including gas bombarding thermal evaporation, plasma and electrode.

Abstract: The present invention provides a novel manufacturing method for coloring and lustering substance, especially suitable for coloring and lustering a carbonizable substance, without using pigments or dyes. The method utilizes the relationship between heat, gas and time to allow a substance to directly form and change color. The color-forming or color-changing phenomena is due to the natural quantity change effects caused by the heat, gas and time, which comprises at least one kind of color, color series or color and luster change.