The present invention relates generally to a yam making method, which makes characteristics of a graphene-containing attaching material present in a yarn to enhance temperature-increasing and warm-keeping properties of clothing.
In the wintertime, people put on heavy clothing to keep themselves warm. Traditionally, warm-keeping clothing is primarily made of cotton or wool, and after the development of the chemical fiber industry, yarns made of man-made fibers are used.
For the traditional warm-keeping clothing, the thickness of the clothing is generally in proportion to the demand for warm keeping, so that body temperature may be isolated by the thickness. The thicker the clothing is, the less degree the heat is dissipating. However, thick clothing indicates more material is consumed and the person wearing the clothing may suffer reduced activity, and more spaces are needed for stowage with the change of seasons.
Nowadays, polar fleece technology and fibers added with mineral-based far infrared light are also used. However, polar fleece may generate a great lot of plastic particles and plastic fibers, and such plastic particles and plastic fibers cannot be intercepted by the sewage systems, nor be effectively blocked by the sewage treatment plants and will attach to various substances, including toxicant organic compounds, algae, and microorganisms, in their ways of flowing toward the oceans, and would, afterwards, be consumed by innocent aquatic organisms, including fishes, shrimps, shellfishes and crabs, all being hard to avoid such a situation. Such plastic particles so consumed accordingly enter the food chains. The related contamination will eventually be accumulated in the large-sized aquatic animals, and even human bodies, and this, as revealed in contemporary studies, leads to human cancels, lowered fertility, reduced immunity, and monstrous births. In consideration of environmental protection, fleece clothing will be gradually weeded out.
Further, some manufacturers make addition, in the form of far infrared powder, such as zirconium oxide, in the processes of making fibers. However, in the subsequent processes of yam formation, in which pigments and setting agents are added, the far infrared particles are set further away from human body. Further, in the winters when sunlight is generally short, the far infrared powder may not get fully effective, and cannot achieve the desired functions of warm keeping and temperature rising.
Disclosed is a yarn making method, which comprises a raw-material yarn;
first rollers, which pull the raw-material yarn;
an entangling point generator, which is arranged posterior to the first rollers to subject the yarn to jet-forming and generating of entangling points;
a cleansing chamber, which is arranged posterior to the entangling point generator to cleanse the yarn that has generated the entangling points;
a material chamber, which is provided with a graphene-containing attachment material to have the yarn that has generated the entangling points and has been cleansed attached with the graphene-containing attachment material;
second rollers, which are arranged posterior to the material chamber to pull the yarn that has past the entangling point generator, the cleansing chamber, and the material chamber;
a heating chamber, which is arranged posterior to the second rollers to have the graphene-containing attachment material provided from the material chamber securely attached to each individual fiber of the yarn by means of heat-setting;
third rollers, which are arranged posterior to the heating chamber to control a heating time of the yarn in the heating chamber; and
fourth rollers, which are arranged posterior to the third rollers to wind and shape the processing-completed yarn.
In the method, the raw-material yarn includes polyester false-twisted filament, nylon false-twisted filament, polyester/nylon filament, polyester/nylon fiber, and polyester/cotton blended yarn. The raw-material yarn is arranged in a yarn roll that is disposed on a yarn release stand. The first rollers pull forward the raw-material yarn, and the first rollers pull 100-1000 meters per minute to pull the raw-material yarn to subsequent working stages. The entangling point generator is arranged posterior to the first rollers to subject the yarn to jet-forming of entangling points, meaning an air jet nozzle is used in processing polyester or polyamide textured yarn, so as to have fibers generating point-like packed entangling phenomena to make 80-120 entangling points in each meter of the yarn. The cleansing chamber is arranged posterior to the entangling point generator to cleanse the yarn that has generated the entangling points, wherein the cleansing chamber applies a clear water rinsing process to wash out residual oil stains on the yarn in order to prevent the oil stains, generated after the yarn is being subjected to forming of the entangling points, from affecting attaching of the attachment material thereto. The cleansed yarn is then fed to the material chamber for processing. The material chamber is provided with the attachment material to have the attachment material attached to the yarn that has generated the entangling points and has been cleansed. The attachment material can be a graphene-containing attachment material, and the yarn that has generated the entangling points and has been cleansed is attached with the graphene-containing attachment material.
The graphene attachment material comprises water, a high molecular polymer, and graphene particles. The high molecular polymer is acrylic, or polyurethane (PU), or polyester. After stirring, the graphene-containing attachment material is attached to the yarn that passes through the material chamber. Any object having a temperature higher than absolute zero degree shows radiation. The normal temperature of a human body is around 37° C. and the radiation that is calculated with known formulas has an electromagnetic wave peak of around 9.5 μm. An object may readily absorb energy close to a radiation peak value thereof, and thus, far infrared light having a wavelength range of 8-14 μm can be easily absorbed by a human body. Graphene when heated generates far infrared light of 8-14 μm that is close to human body wavelength. The far infrared light generated by heated graphene is very close to human body wavelength, both being 8-15 μm. When wavelengths that are equivalent are interacting with each other, a resonant phenomenon occurs. When a resonance effect occurs on biological cells, far infrared thermal energy may deeply get into the subcutaneous tissues, making capillary blood vessels expanding and enhancing blood circulation, and thus helping increasing body temperature, this being appreciated from the test report of Attachment 1.
Further, common graphene particles are mostly of a geometric shape of circle. A circle makes any incident energy hard to control due to the surface curvature and is hard to resonate with the far infrared light radiating from human body. In view of such, specifically manufactured graphene particles that are rectangular in shape having a length of 3-20 μm, a width of 8-25 μm, and a thickness of 3-12 nm are used such that when the rectangular graphene particles are located on a surface of the yarn, they can more easily resonate with the radiation generated by the human body.
The second rollers are arranged posterior to the material chamber to pull the yarn that has past the entangling point generator, the cleansing chamber, and the material chamber. The heating chamber is arranged posterior to the second rollers to have the attachment material provided from the material chamber securely attached to each individual fiber of the yarn by means of heat-setting, and the heating chamber has a heating temperature of 100-600 degrees Celsius. The third rollers are arranged posterior to the heating chamber to control the heating time of the yarn in the heating chamber, and the third rollers pull 100-1000 meters per minute to control the heating time of the yarn in the heating chamber. The fourth rollers are arranged posterior to the third rollers to wind and shape the yarn that has been completed the processing.
As such, the yarn so completed the processing possesses the property of the graphene-containing attachment material.
Referring to
First rollers (2) pull the raw-material yarn (1), the first rollers being operable to pull 100-1000 meters per minute to pull the raw-material yarn (1) to subsequent working stages.
An entangling point generator (3) is arranged posterior to the first rollers (2) to subject the raw-material yarn (1) to jet-forming of entangling points (11), wherein the processing uses an air jet nozzle (31) to make the fiber generate packed entangling phenomena in the form of node points, meaning pressurized air is introduced into the nozzle to generate swirling flows to make the yarn possess homogenate physical property to facilitate processing in the subsequent working stages.
The entangling point generator (3) uses the air jet nozzle (31) to cause, during the processing, polyester or polyamide textured yarn to have fibers generating point-like packed entangling phenomena so as to make 80-120 entangling points in each meter of the yarn.
A cleansing chamber (4) is arranged posterior to the entangling point generator (3) to cleanse the yarn (1) that has generated the entangling points, wherein the cleansing chamber is operated with clear water rinsing to remove residual oil and contaminants from the yarn, and clear water rinsing can be rinsing through dipping in water or spraying of water, so as to make the raw-material yarn (1), before the next working stage, keep the yarn clean and free of foreign object attached thereto.
A material chamber (5) is provided with a graphene-containing attachment material (51), so that the raw-material yarn (1) that has generated the entangling points and has been cleansed is attached with the graphene-containing attachment material (51), wherein the graphene-containing attachment material (51) includes: a high molecular polymer and water, and the high molecular polymer is acrylic or polyurethane (PU) or polyester, and a ratio of graphene in the entirety of attachment material is from 0.1 percent to 3 percent; and a ratio of the high molecular polymer is from 10 percent to 69.9 percent, a ratio of water being from 30 percent to 89.9 percent, wherein graphene, high molecular polymer, and water are stirred for 20 to 28 hours with a stirrer motor at a rotational speed of 1000-5000 revolutions per minute and are then introduced into the material chamber (5) to serve as the attachment material (51), wherein graphene can be of a rectangular shape having a length of 3-20 μm, a width of 8-25 μm, and a thickness of 3-12 nm, see a third-party temperature rise test report provided in Attachment 1.
Second rollers (6) are arranged posterior to the material chamber (5) to pull the raw-material yarn (1) that has past the entangling point generator (3), the cleansing chamber (4), and the material chamber, wherein the second rollers pull forwards 100-1000 meter per minute to provide a pulling force for the raw-material yam (1) to pass through the previous working stages.
A heating chamber (7) is arranged posterior to the second rollers (6) to have the graphene-containing attachment material (51) provided from the material chamber (5) securely attached to each of individual fibers of the raw-material yarn (1) by means of heat-setting, wherein the heating chamber (7) has a temperature of 100-600 degrees Celsius.
Third rollers (8) are arranged posterior to the heating chamber (7) to control a heating time of the raw-material yarn (1) in the heating chamber, wherein the third rollers (8) have a rotational speed for pulling 100-1000 meters per minute and allows the raw-material yam (1) passing through the heating chamber (7) to subject to optimum heating for temperature homogeneity at 100-600 degrees Celsius.
Fourth rollers (9) are arranged posterior to the third rollers (8) to wind the yarn so processed for shaping, wherein the fourth rollers pull forward 100-1000 meters per minute to wind and shape the processing-completed yarn.
As shown in
The textured yarn so obtained through the above-described stages possesses the characteristics of the graphene attachment material according to the present invention, as shown in the far infrared light average radiation rate of Attachment 1 and the temperature rise test of the present invention of Attachment 2, and heat radiation of regular powder including far infrared particles of
Number | Date | Country | Kind |
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110118719 | May 2021 | TW | national |