RU97134U1 - COMPLEX SYNTHETIC THREAD, INCLUDING YARN, WITH ANTI-MICROBIAL PROPERTIES - Google Patents

Abstract

 1. A complex synthetic thread, including yarn, the filamentation index of which is f 97-600, while an antimicrobial additive is introduced into its composition. ! 2. The thread according to claim 1, characterized in that it is made of polyester filaments or fibers. ! 3. The thread according to claim 1, characterized in that the antimicrobial additive contains silver ions. ! 4. The thread according to claim 1, characterized in that it is made textured. ! 5. The thread according to claim 1, characterized in that the index of its linear density is 26-500 tex.

Description

The utility model relates to the textile industry, namely to a complex multifilament synthetic yarn modified in the process of its preparation by an additive with antimicrobial action. Such threads are intended for the manufacture of upholstery and technical fabrics, as well as fabrics and knitwear for special clothes and shoes, etc.

Closest to the proposed utility model is a complex synthetic thread, including yarn, with antimicrobial properties, characterized in that its filament index f is 26-96, while an antimicrobial additive is introduced into the composition of this thread (yarn) (RU 90798, class D06M 16/00, published 01/20/2010).

Based on the filamentation index of a known thread or yarn, its use is limited to the manufacture of a hosiery assortment of textiles that, based on their functional purpose, have direct contact with the skin and therefore experience negative effects from various microorganisms on it, including gram-negative and gram-positive bacteria that can cause various stains on these products and give them undesirable odors, as well as their fading, while decree These microorganisms weaken the strength of products and cause their cross-contamination. It should also be noted that these products are intended for individual use.

At the same time, materials and products that are in common use, such as, for example, bedspreads, curtains, special clothing, etc., in turn, can have a negative impact on the consumer in terms of being on them and transferring them from one person to another. unwanted microorganisms.

The technical problem to which this solution is directed is to develop an antimicrobial synthetic thread or yarn suitable for the manufacture of upholstery and technical fabrics with high performance properties, as well as fabrics and knitwear for special clothes and shoes.

The technical result of the utility model is to provide a prolonged antimicrobial effect, contributing to a significant slowdown in the growth on the surface of the above products of pathogenic organisms.

The technical result is achieved in a utility model using the following set of features.

A complex synthetic thread, including yarn, is characterized by the fact that an antimicrobial additive is introduced into its composition (in the process of production), in other words, it is modified with an additive with antimicrobial action, while its filamentation index is in the range of 97-600. In an advantageous embodiment of the utility model, the thread, including yarn, is made of polyester filaments (fibers), and the antimicrobial additive (antimicrobial additive) contains silver ions.

Also, other synthetic yarns or fibers, for example, such as polypropylene, polyacrylonitrile or polyamide yarn or fiber, can be used as the basis of a multifilament synthetic yarn.

The proposed thread can be made textured, which will increase the antimicrobial properties of the textile product made from it by increasing the contact area of the threads (fibers) with the skin, adding to this an improvement in its performance properties, in particular, such as elasticity and resilience.

The linear density of the proposed thread (yarn) lies in the range of values: 26-500 tex.

The basis of the proposed complex thread (yarn) has a multifilament, i.e. consisting of many fine filaments or fibers (a few micrometers thick each), structure. This allows you to increase the performance properties of products made from such a thread or yarn, such as: air permeability, vapor permeability and hygroscopicity. In addition, products from such yarns are characterized by lightness and have good handling properties.

In accordance with the proposed utility model, a synthetic material, such as polyethylene terephthalate (PET), is used as the polyester backbone of the thread (yarn). Unlike natural ones, this thread (yarn) is characterized by significant mechanical abrasion and tear strength, as well as elasticity and biostability.

The filaments or fibers that make up the proposed thread (yarn) have a high modulus of elasticity, due to which the products made from it perfectly retain their shape and restore it even after prolonged exposure to external force, so they do not wrinkle and are stable in shape. The specified thread (yarn) is characterized by a low specific gravity.

The proposed thread (yarn) is resistant to acids and alkalis, as well as oxidizing agents and reducing agents.

Textile, including knitted, products from these chemically inert threads (yarn) can be worn by the most sensitive (allergic-dependent) people.

The antimicrobial additive (additive) of the thread (yarn) can contain silver in various forms (ions, salts, metal), which enhances the above properties.

An additive with an antimicrobial effect, for example, containing silver ions, has a multiple effect on bacterial life processes, preventing the growth of fungi, gram-positive and gram-negative bacteria and mold, as well as various infections, thereby improving body hygiene and reducing the unpleasant odor of sweat if performed from the proposed threads (yarn) of special clothes or shoes.

Due to the modification of the thread in the process of its production, and not the subsequent processing of the finished threads or products obtained from them by dipping or applying antimicrobial agents on them, the additive provides a long-lasting effect, ease of integration, minimal fading, no friction and clogging during spinning, as well as lack of mechanical deformation of twisted fibers.

The drawing shows a diagram of a process for producing antimicrobial threads (yarn) dyed in bulk.

Amorphous PET granulate through a transport system is first supplied to a daily container 1, from which it passes through a rotary dispenser 2 to a crystallizer 3, where this granulate is heated by circulating air and thoroughly mixed to prevent the granules from sticking together.

After completion of the crystallization process, the granulate is poured into a vertical shaft dryer 4, from which the dried granulate is piped to a gravimetric unit 5.

Polymer dye concentrate (PAC) and antimicrobial additive (AD) are loaded into the appropriate containers 6 and 7, of which through conveyors they are fed to dryers 8 and 9, and then to the gravimetric unit 5. From the gravimetric unit 5, the granulate mixture, which includes: PET, PAC and HELL, through a loading funnel enters the extruder 10, where they are melted and homogenized.

The resulting melt is fed to the molding heads 11, and from there it flows under pressure to the four-chamber spinning metering pumps 12, each of which measures the melt flow into four dies.

Next, the melt is fed by a spinning pump to a spinneret kit, where it is filtered fine. After exiting the spinneret, the melt trickles fall into the blower shaft 13. Due to the difference between the molding speed and the winding speed on the winding heads 14, an elementary thread or yarn fibers are drawn.

Since a bacterium-resistant additive with an antimicrobial effect, containing silver ions, is added to the mass of threads during their formation, and not to their surface, it does not migrate from the fabric to the skin, and therefore is constantly stored in the fabric from these threads, even after repeated washing .

To confirm the antibacterial properties of the threads, several experiments were carried out, in particular, sterility was seeded in accordance with the order of the USSR Ministry of Health No. 720.

The complex polyester thread made in accordance with the above was cut into small pieces 1-2 cm long and pulled apart for possible germination of microorganisms.

Sowing was carried out in 3 tubes with thioglycolic medium, 3 tubes with Saburo medium, and 3 tubes with Hottinger sugar broth, placing 4-5 pieces of test material in each. The material was taken in 5 repetitions at different lengths of the thread (upper, lower, and from the center). For control, seeding was performed on ENDO, Saburo and blood agar media.

The experimental results are summarized in table 1.

Table 1 the control Polyester thread with silver ions repetitions Thioglycol medium 0 0 0 0 0 0 0 0 0 0 0 Saburo 0 0 0 0 0 0 0 0 0 0 0 Sugar Broth 0 0 0 0 0 0 0 0 0 0 0

Also tested polyester and polypropylene filaments with silver ions against several bacteria. The experimental results are summarized in tables 2 and 3.

table 2 Thread pattern Test bacteria Escherichia coli Staphylococcus aureus A AT FROM BUT AT FROM Polyester thread
with silver ions 2 3.6 2.2 2 3.8 2.2

Test bacteria:

Staphylococcus aureus - ATCC ^TM 29213

Escherichia coli - ATCC ^TM 25922

The number of parallel measurements is three.

A - the specified number of bacteria / ml according to McFarland before inoculation

B is the average number of bacteria / ml according to McFarland after inoculation without adding strands after 24 hours.

C is the average number of bacteria / ml according to McFarland after inoculation with the addition of threads after 24 hours.

Table 3 Thread pattern Test bacteria Enterococcus faecalis Candida albicans A AT FROM BUT AT FROM Polypropylene thread
with silver ions 2 3.2 2.2 2 4.6 2.2

Test bacteria:

Enterococcus faecalis - ATCC ^TM 29212

Candida albicans - ATCC ^TM 2091

The number of parallel measurements is three.

A - the specified number of bacteria / ml according to McFarland before inoculation

B is the average number of bacteria / ml according to McFarland after inoculation without adding strands after 24 hours.

C is the average number of bacteria / ml according to McFarland after inoculation with the addition of threads after 24 hours.

Claims (5)

1. A complex synthetic thread, including yarn, the filamentation index of which is f 97-600, while an antimicrobial additive is introduced into its composition. 2. The thread according to claim 1, characterized in that it is made of polyester filaments or fibers. 3. The thread according to claim 1, characterized in that the antimicrobial additive contains silver ions. 4. The thread according to claim 1, characterized in that it is made textured. 5. The thread according to claim 1, characterized in that the index of its linear density is 26-500 tex.