阅读说明：本技术 一种抗戳破型布料的加工方法 (Processing method of anti-puncture cloth ) 是由 位山 于 2019-11-25 设计创作，主要内容包括：本发明提供了一种抗戳破型布料的加工方法,主要通过铁粉、锌粉、铝粉、氧化钙、氧化铁、氧化锌、腈纶、聚芳醚砜、水性聚氨酯乳液、成布助剂、增强剂、增韧剂、纳米弹性体复合纤维、竹原纤维、甲壳素纤维、蒙脱石粉末、纳米银、奥米矿物纤维、偶联剂、纤维素酶溶液和羟乙基纤维素混合制取,本发明设计合理,加工方便,不仅能够有效提高产品的韧性,同时,也能够增强布料本身的强度,从而有效提高了布料的有益效果。(The invention provides a processing method of anti-puncture cloth, which is mainly prepared by mixing iron powder, zinc powder, aluminum powder, calcium oxide, iron oxide, zinc oxide, acrylic fibers, polyarylethersulfone, aqueous polyurethane emulsion, a cloth forming auxiliary agent, a reinforcing agent, a toughening agent, nano elastomer composite fibers, bamboo fibers, chitin fibers, montmorillonite powder, nano silver, Ormi mineral fibers, a coupling agent, a cellulase solution and hydroxyethyl cellulose.)

1. The processing method of the anti-puncture cloth is characterized by comprising the following specific steps:

s01, adding the natural fiber mixed aqueous solution into a stirrer, adding a small amount of metal powder and metal oxide, mixing and stirring uniformly,

s02: after uniformly stirring, adding acrylic fibers, polyarylethersulfone, aqueous polyurethane emulsion, a cloth forming auxiliary agent, a reinforcing agent, a toughening agent, nano elastomer composite fibers and bamboo fibers one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s03: stirring for more than half an hour under the condition of 80-85 ℃, adding chitin fiber, montmorillonite powder, nano silver, Ormi mineral fiber, coupling agent, cellulase solution and hydroxyethyl cellulose one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s04: adding the mixture into a 3D printer, and preparing the cellosilk by using the 3D printer;

s05: making natural fiber yarn into bottom thread, making synthetic fiber yarn into upper thread, and weaving cloth with inner layer of natural fiber and outer layer of synthetic fiber on a loom;

s06: dyeing the woven cloth according to the needs, soaking the cloth in clean water, and then drying the cloth by spin-drying the water to ensure that the water content of the cloth is 5%;

s07: placing water with the weight 10 times that of the cloth in a finishing cylinder, heating to 75 ℃, putting the antibacterial agent into the water according to the weight percentage, wherein the dosage of the antibacterial agent is 3 percent of the weight of the cloth, and uniformly stirring;

s08: then putting the cloth into a finishing cylinder, and stirring for 35 minutes;

s09: and fishing out the cloth, drying in a dryer, and finally shaping in a shaper to obtain the finished product.

2. A method of processing a puncture resistant fabric as recited in claim 1, wherein: in the above step S01, the proposed metal powder includes iron powder, zinc powder, and aluminum powder.

3. A method of processing a puncture resistant fabric as recited in claim 2, wherein: the metal powder comprises the following components in parts by mass: 0.03-0.04g of iron powder, 0.03-0.04g of zinc powder and 0.03-0.04g of aluminum powder.

4. A method of processing a puncture resistant fabric as recited in claim 1, wherein: in the above step S01, the proposed metal oxide includes calcium oxide, iron oxide, and zinc oxide.

5. The processing method of the puncture-resistant cloth according to claim 4, wherein the processing method comprises the following steps: the plant comprises the following components in parts by mass: 0.03-0.05g of calcium oxide, 0.03-0.05g of iron oxide and 0.03-0.05g of zinc oxide.

6. A method of processing a puncture resistant fabric as recited in claim 1, wherein: in the step S02, the weight parts of the material components are as follows: 15-20g of acrylic fibers, 1-2g of polyarylethersulfone, 1-2g of aqueous polyurethane emulsion, 0.5-1g of cloth forming auxiliary agent, 0.5-1g of reinforcing agent, 0.2-0.3g of toughening agent, 1-5g of nano elastomer composite fibers and 5-8g of bamboo fibrils.

7. A method of processing a puncture resistant fabric as recited in claim 1, wherein: in the step S03, the weight parts of the material components are as follows: 5-8g of chitin fiber, 1-2g of montmorillonite powder, 0.01-0.02g of nano silver, 1-2g of Ormi mineral fiber, 0.2-0.3g of coupling agent, 1-2g of cellulase solution and 1-2g of hydroxyethyl cellulose.

Technical Field

The invention mainly relates to the technical field of cloth processing, in particular to a processing method of puncture-resistant cloth.

Background

The cloth is a material commonly used in decorative materials. Comprises various fabrics such as chemical fiber carpets, non-woven wallcoverings, linen, nylon fabrics, colored rubberized fabrics, flannel and the like. Cloth plays a considerable role in decorative displays, often a major non-negligible effort in the overall sales space. A large amount of cloth is used for wall surface decoration, partition and background treatment, and a good commercial space display style can be formed. In the existing cloth, the cloth is easy to puncture due to the limitation of the material of the cloth, so a brand new cloth needs to be developed, and the cloth modification measure is performed by changing the material.

Disclosure of Invention

The invention mainly provides a processing method of a puncture-resistant cloth, which is used for solving the technical problems in the background technology.

The technical scheme adopted by the invention for solving the technical problems is as follows:

a processing method of a puncture-resistant fabric comprises the following specific steps:

s01, adding the natural fiber mixed aqueous solution into a stirrer, adding a small amount of metal powder and metal oxide, mixing and stirring uniformly,

s02: after uniformly stirring, adding acrylic fibers, polyarylethersulfone, aqueous polyurethane emulsion, a cloth forming auxiliary agent, a reinforcing agent, a toughening agent, nano elastomer composite fibers and bamboo fibers one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s03: stirring for more than half an hour under the condition of 80-85 ℃, adding chitin fiber, montmorillonite powder, nano silver, Ormi mineral fiber, coupling agent, cellulase solution and hydroxyethyl cellulose one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s04: adding the mixture into a 3D printer, and preparing the cellosilk by using the 3D printer;

s05: making natural fiber yarn into bottom thread, making synthetic fiber yarn into upper thread, and weaving cloth with inner layer of natural fiber and outer layer of synthetic fiber on a loom;

s06: dyeing the woven cloth according to the needs, soaking the cloth in clean water, and then drying the cloth by spin-drying the water to ensure that the water content of the cloth is 5%;

s07: placing water with the weight 10 times that of the cloth in a finishing cylinder, heating to 75 ℃, putting the antibacterial agent into the water according to the weight percentage, wherein the dosage of the antibacterial agent is 3 percent of the weight of the cloth, and uniformly stirring;

s08: then putting the cloth into a finishing cylinder, and stirring for 35 minutes;

s09: and fishing out the cloth, drying in a dryer, and finally shaping in a shaper to obtain the finished product.

Further, in the above step S01, the proposed metal powder includes iron powder, zinc powder, and aluminum powder.

Further, the metal powder comprises the following components in parts by mass: 0.03-0.04g of iron powder, 0.03-0.04g of zinc powder and 0.03-0.04g of aluminum powder.

Further, in the above step S01, the proposed metal oxide includes calcium oxide, iron oxide, and zinc oxide.

Further, the plant comprises the following components in parts by mass: 0.03-0.05g of calcium oxide, 0.03-0.05g of iron oxide and 0.03-0.05g of zinc oxide.

Further, 15-20g of acrylic fibers, 1-2g of polyarylethersulfone, 1-2g of aqueous polyurethane emulsion, 0.5-1g of cloth forming auxiliary agent, 0.5-1g of reinforcing agent, 0.2-0.3g of toughening agent, 1-5g of nano elastomer composite fibers and 5-8g of bamboo fibrils.

Further, in the step S03, the material components in parts by weight are as follows: 5-8g of chitin fiber, 1-2g of montmorillonite powder, 0.01-0.02g of nano silver, 1-2g of Ormi mineral fiber, 0.2-0.3g of coupling agent, 1-2g of cellulase solution and 1-2g of hydroxyethyl cellulose.

Compared with the prior art, the invention has the beneficial effects that: the cloth is reasonable in design and convenient to process, and not only can the toughness of the product be effectively improved, but also the strength of the cloth can be enhanced, so that the beneficial effect of the cloth is effectively improved.

Detailed Description

The present invention will be specifically described below with reference to examples.

The main processing method of the invention comprises the following steps: s01, adding the natural fiber mixed aqueous solution into a stirrer, adding a small amount of metal powder and metal oxide, mixing and stirring uniformly,

s02: after uniformly stirring, adding acrylic fibers, polyarylethersulfone, aqueous polyurethane emulsion, a cloth forming auxiliary agent, a reinforcing agent, a toughening agent, nano elastomer composite fibers and bamboo fibers one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s03: stirring for more than half an hour under the condition of 80-85 ℃, adding chitin fiber, montmorillonite powder, nano silver, Ormi mineral fiber, coupling agent, cellulase solution and hydroxyethyl cellulose one by one, mixing and stirring while heating, and controlling the temperature to be 80-85 ℃;

s04: adding the mixture into a 3D printer, and preparing the cellosilk by using the 3D printer;

s05: making natural fiber yarn into bottom thread, making synthetic fiber yarn into upper thread, and weaving cloth with inner layer of natural fiber and outer layer of synthetic fiber on a loom;

s06: dyeing the woven cloth according to the needs, soaking the cloth in clean water, and then drying the cloth by spin-drying the water to ensure that the water content of the cloth is 5%;

s07: placing water with the weight 10 times that of the cloth in a finishing cylinder, heating to 75 ℃, putting the antibacterial agent into the water according to the weight percentage, wherein the dosage of the antibacterial agent is 3 percent of the weight of the cloth, and uniformly stirring;

s08: then putting the cloth into a finishing cylinder, and stirring for 35 minutes;

s09: and fishing out the cloth, drying in a dryer, and finally shaping in a shaper to obtain the finished product.

Within the present invention, the different component contents of the materials are as follows.