KR100580847B1 - A ANTIBACTERIA FIBER PROCESSED WITH nm,PLATINUM COLLOID SOLUTION AND THE PROCESSE METHOD - Google Patents

Abstract

The present invention relates to an antimicrobial fiber treated with a nano platinum colloidal solution and a method for producing the fiber. The fabric is subjected to anionization with an anionic activator, and the nanoplatinum colloidal solution is cationicized with a cationic dispersant and then cationic. The nano platinum colloid is added to the anionized fiber to ionize the nano platinum to the fibrous tissue and fix it with a water-soluble binder to obtain high antimicrobial fiber.

Anionization of fiber, nano platinum colloid, positive ionization treatment, antibacterial fiber.

Description

Antimicrobial Fiber Treated with Nano Platinum Colloidal Solution and Manufacturing Method Thereof {A ANTIBACTERIA FIBER PROCESSED WITH nm, PLATINUM COLLOID SOLUTION AND THE PROCESSE METHOD}

The present invention relates to an antimicrobial fiber treated with a nano platinum colloidal solution and a method of manufacturing the same.

Here, the fiber is intended to include natural fibers and synthetic fibers, including fabrics.

There is a long demand for imparting antimicrobial properties to fibers. This is because the infection of contact infectious bacteria, such as clothing, socks, towels, daily necessities, etc., which come into contact with the human body due to the deepening of modern natural environmental pollution, causes serious harm to human health.

In the early stages of antimicrobial processing of fibers, aromatic halogen compounds and organosilicon quaternary ammonia salts were used as antimicrobial agents, and recently, metals such as copper and silver have been used.

An example of the prior art of antimicrobial treatment using nano silver (Ag) colloid is disclosed in the publication of published patent application No. 0000623 (published on April 4, 2000). This is because the nano silver colloidal solution having antimicrobial activity is adsorbed on the fiber to inhibit the growth of bacteria, fungi, yeast, etc. In the case of copper, there is a problem that the activity is harmful to the human body by generating copper oxide (酸化 銅) is strong, and silver (Ag) is a relatively stable metal material as compared to copper and is usefully applied to antibacterial fibers.

The present invention is a new antibacterial fiber and a method for producing a high antibacterial fiber and a high antibacterial effect of the high strength and antibacterial as a result of various tests of the conventional antimicrobial fiber using nano platinum as well as copper and silver Developed.

Platinum (Pt) with atomic number 78 and atomic weight 195.09 is an expensive precious metal and has good chemical stability and good electrical conduction. It is mainly used for terminals of electrical equipment, integrated circuits, sensitive electrodes of various test equipment, elements of chemical manufacturing equipment, and various machinery. It is used as an element of. Thus, little attention has been paid to the antimicrobial activity of platinum, which is widely used in the industry.

However, in the fine powder state, platinum has a characteristic of absorbing more than 100 times the volume of hydrogen and oxygen. Since hydrogen and oxygen are absorbed, they may be used as catalysts for oxidation and reduction.

In the present invention, the fine powder of platinum (Pt) focuses on the absorption of oxygen and hydrogen and the activation of oxygen, and it is related to the killing or reproduction inhibition of bacteria by the activation of oxygen and hydrogen. As a result, nano platinum inhibits the metabolism of oxygen and digestion of microorganisms such as bacteria and fungi, thereby confirming the antimicrobial effect of inhibiting the death and reproduction of bacteria.

The nano platinum colloid used in the present invention is colloidalized by collecting platinum particles (particle size of 1 to 150 nm) evaporated by heating the platinum piece in a high vacuum atmosphere by heat transfer.

In the present invention, as a result of various studies to uniformly and firmly adsorb the nano platinum having such an antimicrobial action to the fiber tissue, the fiber fabric is anionized using an anionic surfactant, and the nano platinum colloid is cationicized using a cationic dispersant After treatment, the cationized nano platinum colloidal solution was added to the anionized fiber treatment tank and stirred to adsorb nano platinum to the fiber tissue by ion bonding. Next, an acrylic soft binder used for fixing the dye was added to the fiber tissue to which the nano platinum was adsorbed, and the nano platinum adsorbed to the fiber tissue was fixed to the fiber to obtain the antimicrobial fiber of the present invention.

The antimicrobial fiber of the present invention is because the fiber and nano platinum are dispersed and adsorbed uniformly with a strong adsorption force primarily by ionic bonding, and then the nano platinum adsorbed by the soft binder is solidified. The nano platinum is hardly eliminated and remains, and the fastness is very strong. In addition, since platinum is a physically and chemically relatively stable metal material, even if the antimicrobial fiber is boiled with an alkaline detergent at a high temperature or ironed at a high temperature, there is no deterioration of platinum and the antibacterial function of platinum is maintained for a long time. In addition, due to the activity of nano-platinum dispersed and adsorbed on the fiber tissue and the emission of far-infrared rays, the killing and propagation of various bacteria, molds, etc. in contact with the fibers and fabrics are maintained, and the hygiene of the antibacterial fiber products can be improved.

Compared with copper and silver, platinum is expensive, but the amount of 1000 ppm nano platinum colloid used in fiber is only 0.1-2.0% by weight, so that antibacterial activity is evident. Given the low concentration of nano-platinum colloids in use, the economy is never lower than that of copper or silver.

In addition, since the nanoplatinum colloid has a wide range of use, it can be easily purchased in chemicals and chemicals, and thus there is no difficulty in supplying the material to the production of the nanoplatinum colloidal antimicrobial fiber of the present invention and there is no need to perform the nanoplatinum colloid manufacturing process separately. Fiber. Fabrics are easier to manufacture.

(Example)

1. Anionization Process of Fiber

10 L of water is added to the treatment tank, and 1.25 kg to 1.50 kg of fabric and fabric are immersed therein, and 50 g of anionic surfactant is added thereto and stirred for 30 minutes. At this time, the water temperature is maintained at 30 ° C. for cotton and bristle, and about 60 ° C. for synthetic fibers such as nylon and polyester. The fiber becomes anionic by the anionic surfactant during agitation and has high affinity with the cationic material. As the anionic surfactant, for example, lauric acid, oleic acid, stearic acid salt and the like can be used as fatty acid salts.

2. Nano platinum cationization process

10-20 g of a nano-platinum colloid (particles 1-150 nm, concentration 1000 ppm) solution and 20 g of a cationic dispersant (trade name SD-900 Samdu Co., Ltd.) are mixed and stirred for 30 minutes to cationize. The cation dispersant is a polyamion derivative composed of a dark brown transparent liquid, having an acidic strong cation of about pH 4.0 ± 1.0, and readily dissolved in cold and hot water. The dispersant is a dispersant used to easily disperse and dye pigments and Anion-based dyes by fiberizing fibers during fiber dyeing. In the present invention, it was employed for the Cation and dispersion of nano platinum colloid.

3. Nano platinum colloid adsorption treatment process

The nano-doped colloidal solution cationicly treated by the second step is added to a treatment tank of the anionized fiber by the first step, followed by stirring for 30 minutes. The nano-platinum is added by ion bonding between the added nano platinum colloid and the fiber. The particles are evenly dispersed and adsorbed into the fiber tissue. At this time, since all of the added platinum nano-colloid is adsorbed to the fibrous structure, almost no platinum particles remain in the solution of the treatment tank.

4. Fixation process

Nano platinum colloid is adsorbed by ionic bond to fiber by the third step, and then 30 g of acrylic water-soluble soft binder (SD-BINDER Samdu Co., Ltd.) is added to the fiber and stirred. During stirring, the binder adheres to the fibrous tissue to fix the nano platinum to the fibrous tissue.

The acrylic binder is an emulsion that polymerizes acrylic acid ester, and is an adhesive that solidifies the coloring of the aqueous pigment and forms an excellent stretch and film. In this invention, it employ | adopted for fixation of nano platinum.

5. Finishing process

The nanoplatinum antimicrobial fiber of the present invention is obtained by adsorbing nanoplatinum to the fibers by ion bonding, fixing them with a binder, and then drying the fibers and woven fabrics in a treatment tank, washing them with sufficiently purified water, dehydrating and drying them.

The nano platinum antimicrobial fiber of the present invention has high fastness and, in the case of socks or panties, the residual amount of platinum was 70% or more even after 50 washings.

In addition, the far-infrared emissivity (5 ~ 20㎛) of nano platinum-treated fabric was 0.890 and the radiation energy (W / m 2) was 3.59 × 10 ² .

In addition, the antibacterial test against strain 1 (Stapylococcusaureus ATCC 6538) and strain 2 (Klebsiella pneumoniae ATCC 4352) resulted in 99.9% death after 18 hours.

Fiber or woven fabric of the present invention can improve the safety of hygiene to the human body of various fibers and textile products with good fastness and strong antibacterial action.

Since the antimicrobial fiber of the present invention is uniformly dispersed and adsorbed with a strong adsorption force primarily by ionic bonding of fibers and nano platinum, and then solidified the nano platinum adsorbed by a soft binder, nano platinum is hardly washed even after repeated washings. It is not eliminated and the fastness is strong.                     

In addition, since platinum has high physical stability, there is no change in platinum even when the fiber is treated at high temperature, so even if the fabric is boiled with alkaline detergent or ironed, there is no change in platinum and the antibacterial function of platinum lasts for a long time.

In addition, by maintaining the activity of the nano-platinum dispersed and adsorbed on the fiber and far-infrared radiation, it is possible to maintain the killing and propagation control of various bacteria, molds, etc. in contact with the fiber or fabric, thereby improving the hygiene of the human body of the textile product.

In addition, the nano platinum colloid is a new nano platinum antimicrobial fiber because the antibacterial purpose is achieved by adsorbing a small amount of 0.1 to 2.0% at a concentration of only 1000 ppm, and it can be economically inexpensive without inferior economic efficiency compared to conventional copper or silver. There is an effect that can be used very usefully for various applications as a fabric.

Claims (2)

1.25 kg to 1.50 kg of the fiber to be treated was immersed in 10 L of water, and 50 g of anionic activator was added thereto, followed by anionization, and cationization of a nano platinum colloid solution having a particle weight of 1 to 150 nm and a concentration of 1000 ppm with a cation dispersant of the same weight. Next, 0.1 to 2.0% by weight of the cationized nano platinum colloid is added to the anionized fiber to adsorb nano platinum to the fiber structure by ion bonding and fixation with 30 g of water-soluble binder. Antibacterial fiber treated with colloidal solution. A first step of dipping 1.25 kg to 1.50 kg of fiber in a 10 l water treatment tank, adding 50 g of anionic surfactant to it, stirring at a water temperature of 30 to 60 ° C., and anionizing the fiber; A second step of cationizing the nano platinum colloidal solution by mixing and stirring the nano platinum colloidal solution having a concentration of 1 to 150 nm and a concentration of 1000 ppm with the same weight; 0.1 to 2.0% by weight of the cationized nano platinum colloidal solution prepared by the second step was added to the fibers of the anionized treatment tank by the first step, followed by stirring to prepare ionic bonds between the nano platinum colloid and the fiber. A third step of dispersing and adsorbing the nano platinum particles to the fiber structure by A fourth step of attaching 30 g of an acrylic water-soluble soft binder to the fiber to which the nano platinum colloid is adsorbed by inductive bonding by the third step and agitating the nano platinum to the fiber structure; Method for producing an antimicrobial fiber treated with a nano platinum colloidal solution, characterized in that the fiber is prepared by the combination of the fifth step of washing with water, dehydration and drying.