RU202668U1 - MULTI-LAYER FIRE RESISTANT SIGNAL FABRIC - Google Patents

Abstract

The utility model relates to a multilayer fire-resistant signal fabric made of two types of threads with different weaving of threads in the layers of the fabric and alternating the warp threads of the upper layer with the warp threads of the lower layer, the upper fabric layer is made of untwisted polyester textured threads with an oxygen index of 28 ÷ 30%, linear density from 11 tex to 25 tex and coated with a fluorescent dye, the lower layer of the fabric is made of polyaramide yarn with an oxygen index of 28-30%, linear density from 5.5 × 2 tex to 18 × 2 tex, the layers are connected in a top-down manner, in this case, the polyester threads are crumpled in the plane of the surface of the fabric until the diameter increases by 2.0–2.5 times, and the filling of the upper layer of the fabric with polyester threads is 0.3–0.5. The utility model makes it possible to create a fire-resistant signal fabric that provides a complex of fire-resistant properties and increased visibility, resistant to insolation, repeated water treatments and dry cleaning. 4 c.p. f-ly, 1 dwg.

Description

The utility model relates to devices of fabrics differing in material, yarn structure and other features of the warp or weft, and more specifically to the device of fabric with refractory threads, which can be used for the manufacture of special fire-resistant signal clothing with reflective safety equipment designed to protect workers in conditions insufficient visibility. High visibility special signal clothing is made of a fluorescent textile material (fabric) that provides high visibility both in daylight in adverse weather conditions and at night in the light of car headlights.

State of the art

The known device is a two-layer fabric reflective sticker on clothing, which is a reflective fabric made from polyester threads with an internal adhesive non-drying layer [RF Patent No. 182418, IPC A41D 13/01, published. 08/16/2018, bul. No. 23].

A device is known for a multilayer fire-resistant fabric for personal protective equipment of the human skin from fire, containing an outer layer of fire-resistant threads and inner layers of natural fibers, the outer layer is made of plain weave, the inner layer is made of waffle weave and additionally contains fire-resistant threads [RF Patent No. 2017871, IPC D03D 15/12, publ. 15.08.1994, bul. No. 13].

The disadvantages of this fabric device are the lack of signal color and low fire-resistant properties.

The closest to the proposed technical solution is the device of a multilayer fire-resistant signal fabric made of threads of two types and containing a non-combustible twisted polyaramide thread. The non-combustible outer layer is made of fire-resistant yarns, and the inner layer is made of twisted wool, cotton or linen fibers. The non-combustible outer layer is a twisted fire-resistant yarn of woolen fiber, containing 1-10% potassium fluorozirconate by weight of the yarn, and the inner layer is made of twisted yarn of woolen, cotton, or linen fiber, or flax fiber containing mass. %: linen fiber - 30:40, cotton fiber - 60:70 or linen fiber 25:40, viscose high modulus fiber 25:35, polyester fiber - 30:50. In this case, the ratio of the incombustible component and the fibers of the combustible component in the fabric is, respectively, (2.2: 4): 1, and the surface density is in the range of 210-650 g / m ² .

The outer incombustible layer in the warp and / or in the weft additionally contains a twisted yarn of polyaramide or polyoxadiazole fibers. The fabric is made in plain dyed or with a printed pattern. [RF patent No. 2196194, IPC D03D 15/00, publ. 10.01.2003, bul. No. 1)

The fabric device does not provide signaling functions, resistance to reflectivity to insolation, washing and dry cleaning and therefore cannot be reused as a material for work clothes in poor visibility conditions.

The essence of the proposal

The technical problem to be solved by the proposed utility model is the creation of a device for a multilayer fire-resistant signal fabric produced on weaving machines of various types without equipment downtime due to the breakage of threads and the exit of defective fabric, which provides a complex of fire-resistant properties and increased visibility, resistant to insolation, multiple water treatments (washing) and dry cleaning.

The technical problem posed is solved by the fact that in the device of a multilayer fire-resistant signal fabric made of threads of two types and containing a non-combustible twisted polyaramide thread, according to the proposal, the interweaving of threads in the layers of the fabric is different and is made by alternating the threads of the base of the upper layer with the threads of the base of the lower layer, the upper layer fabric is made of untwisted polyester textured yarn with oxygen index 28 ÷ 30% linear density from 11 tex to 25 tex and coated with a fluorescent dye, the lower layer of fabric is made of polyaramide threads with oxygen index 28 ÷ 30% linear density from 5.5 × 2 tex up to 18 × 2 tex, the connection of the layers is made in a top-down manner, while the polyester threads are crumpled in the plane of the fabric surface until the diameter increases by 2.0 ÷ 2.5 times, and the filling of the upper layer of the fabric with polyester threads is 0.3 ÷ 0.5 ... The weaving is made by alternating the warp threads of the upper layer with the warp threads of the lower layer 2: 1, 2: 2, 1: 1 and 1: 2, while the weaving of the upper layer can be made on the basis of 2/2 twill, and the weaving of the lower layer is made on the basis of twill 2/2 or the weave of the top layer can be made on the basis of satin 8/3, and the weaving of the lower layer based on satin 4/1 or the weaving of the top layer can be made on the basis of satin 8/5, and the weaving of the bottom layer on the basis of satin 4 / one.

The aforementioned combination of features of the fabric device allows you to create a new fire-resistant signal fabric with the declared properties. Going beyond the proposed limits of the parameters of the structure of the fabric, the use of other threads and types of their weaves do not ensure the achievement of the technical result.

The offered flame retardant signal fabric is produced on high-performance types of looms such as shuttle loom, air rapier loom, shuttleless loom and micro-pad loom. A change in the linear density or the multiplicity of crushing of fire-resistant threads, as well as the parameters of their weaving outside the stated limits, leads to breakage of the threads and a decrease in the productivity of weaving machines.

Connecting layers in a top-down manner, i.e. fixation of tissue layers by means of threads located in the upper layer minimizes the appearance of threads of the lower layer without a fluorescent coating on the front side and provides the necessary fluorescence brightness.

An increase in the diameter (crease) of the threads of the upper layer by 2-2.5 times is ensured by the use of untwisted textured polyester thread, which, with a lower filling ratio and less insertion of threads into the upper layer in relation to the lower one, ensures complete overlap of the threads of the lower layer. The yarns of the lower layer do not wrinkle due to the use of yarns with a high degree of twist and provide a sufficient level of fire resistance.

The top layer of a multilayer fabric made of polyester yarns with a fluorescent coating and the choice of a signal color is due to the peculiarities of the use of materials used for the manufacture of special types of clothing. Fluorescent signal fabrics for clothing must comply with the requirements of GOST 12.4.281-2014. To meet the requirements of GOST 12.4.281-2014, the signal yellow fabric must have a luminance factor of at least 0.76, which is calculated from the coordinates of the color of the luminous flux reflected from the fabric (Tables 1-3). The color coordinates of the luminous flux from a standard source are measured with spectrophotometers. The brightness values should be maintained after sun exposure (exposure to light), after 12 cycles of wet treatments and dry cleaning.

With an increase in the diameter of untwisted threads of the upper layer of fabric with a linear density of 25 tex due to tension and crumpling during fabric production by less than 2.0 times, the brightness coefficient after dry cleaning decreases to 0.6. With an increase in the diameter of the threads of the upper layer of linear density of 11 tex by more than 2.5 times, the brightness coefficient after washing decreases to 0.5 and the downtime of equipment increases due to breakage of the threads.

The proposal is illustrated with a thread weaving pattern and examples.

FIG. 1 Layout and weaving of threads in a multilayer fire-resistant signal fabric

1 - untwisted crumpled polyester textured yarns;

2 - twisted polyaramide yarns

Example 1.

Multilayer fire-resistant signal fabric, made of two-layer threads of two types: untwisted polyester textured thread with oxygen index 29% linear density 18.3 tex and coated with a dispersed fluorescent dye brand "Papillon yellow F-10GTN" and twisted polyaramide thread Nomex linear density 18.3 × 2 tex with an oxygen index of 30%. The interweaving of the threads in the layers of the fabric is made on the basis of twill 2/2 with the connection of the layers in a top-down manner with alternating the warp threads of the lower layer 2: 1 with alternating weft threads of the upper layer with the weft threads of the lower layer 2: 2. The filling factor of the upper fabric layer is 0.3, and the filling factor of the lower layer is 0.6. The weight ratio of polyester yarn to polyaramide yarn is 20:80.

Untwisted polyester threads of the upper layer are crumpled in the plane of the surface of the fabric to increase their diameter (width) by 2.0 times by means of greater tension when the fabric is made on a shuttleless loom. In the proposed fabric device there is no significant change in the diameter (crushing) of the twisted yarns of the lower layer in the plane of the fabric surface. Crumpled threads of the lower layer 1.0. The multilayer fire-resistant signal fabric according to example 1 is produced in an optimal mode without equipment downtime due to breakage of threads and the exit of defective fabric. The areal density of the two-layer fire-resistant signal fabric is 270 g / m ² .

The test results are shown in tables 1, 2.

Example 2.

Multilayer fire-resistant signal fabric, made of two-layer yarns of two types: untwisted polyester textured yarn with oxygen index 28% linear density 25 tex and coated with vat fluorescent dye and twisted polyaramide thread nomex linear density 25 × 2 tex with oxygen index 28%. The interweaving of the threads in the layers of the fabric is made on the basis of twill 2/2 with the connection of the layers in a top-down manner with alternating the warp threads of the lower layer 2: 1 with alternating weft threads of the upper layer with the weft threads of the lower layer 2: 2. The filling factor of the upper fabric layer is 0.5, and the filling factor of the lower layer is 0.6. The weight ratio of polyester yarn to polyaramide yarn is 30:70.

Untwisted polyester threads of the upper layer are crumpled in the plane of the surface of the fabric to increase their diameter (width) by 2.5 times by means of greater tension when making the fabric on a pneumatic rapier loom. In the proposed fabric device, there is no significant change in the diameter (crushing) of the twisted threads. Crumpled threads of the lower layer 1.0. The multilayer fire-resistant signal fabric according to example 2 was produced in an optimal mode without equipment downtime due to thread breakage and the release of defective fabric.

The areal density of the two-layer fire-resistant signal fabric is 290 g / m ² .

Example 3.

Multilayer fire-resistant signal fabric, made of two-layer yarns of two types: untwisted polyester textured yarn with an oxygen index of 30% linear density of 11 tex and coated with a vat fluorescent dye and twisted polyaramide thread nomex with a linear density of 11 × 2 tex with an oxygen index of 28%. The composition of the polyaramide thread: 95% of the mass. meta-aramid fibers, 5% of the mass. para-aramid fibers. The interweaving of the threads in the layers of the fabric is made on the basis of twill 2/2 with the connection of the layers in a top-down manner with alternating the warp threads of the lower layer 2: 1 with alternating weft threads of the upper layer with the weft threads of the lower layer 2: 2. The filling factor of the upper fabric layer is 0.5, and the filling factor of the lower layer is 0.6. The weight ratio of polyester yarn to polyaramide yarn is 30:70

Untwisted polyester threads of the upper layer are crumpled in the plane of the surface of the fabric until their diameter (width) increases by 2.5 times by means of greater tension when the fabric is made on a weaving machine with a microlayer. In the proposed fabric device, there is no significant change in the diameter (crushing) of the twisted threads. Crumpled threads of the lower layer 1.0. The multilayer fire-resistant signal fabric according to example 3 is produced in an optimal mode without equipment downtime due to thread breakage and the release of defective fabric.

The areal density of the two-layer fire-resistant signal fabric is 260 g / m ² .

Example 4. Multilayer fire-resistant signal fabric made of one and a half-layer structure of two types of threads: untwisted polyester textured thread with oxygen index 29% linear density of 18.3 tex and coated with a dispersed fluorescent dye brand "Papilion yellow F-10GTN" and twisted polyaramide density nomex linear density 18.3 × 2 tex with 30% oxygen index. The interweaving of the threads of the upper layer of the fabric is made on the basis of satin 8/3, the lower layer of the fabric is made on the basis of atlas 4/1, the weft threads are located one under the other, and the main threads, intertwining with the weft threads, connect them with alternating warp threads of the lower layer 2: 1 with alternating upper layer weft threads, with lower layer weft threads 2: 1. The filling factor of the upper fabric layer is 0.44, the filling factor of the lower layer is 0.64.

The polyester threads of the upper layer are crumpled in the plane of the surface of the fabric until their diameter is increased by 2.3 times by means of greater tension when the fabric is made on a shuttleless loom. In the proposed fabric device, there is no significant change in the diameter (crushing) of the twisted threads of the lower layer in the plane of the fabric surface. The multilayer fire-resistant signal fabric according to example 4 is produced in an optimal mode without equipment downtime due to broken threads and the release of defective fabric

Example 5 (for comparison). Multilayer fire-resistant signal fabric according to example 1, but with a filling factor of the upper fabric layer of 0.2. The twisted polyester threads of the upper layer are crumpled in the plane of the fabric surface to increase their diameter (width) by 1.9 times.

Example 6 (for comparison). Multilayer fire-resistant signal fabric according to example 1, but with a filling factor of the upper fabric layer of 0.6.

Untwisted polyester threads of the upper layer are crumpled in the plane of the surface of the fabric until their diameter (width) increases by 2.6 times.

When working on a shuttleless weaving machine to obtain polyester threads of the upper layer, crumpled in the plane of the surface, the downtime of equipment due to breakage of threads increases 2.6 times. There is a yield of up to 20% of defective fabric.

Example 7 (for comparison). The multilayer fire-resistant signal fabric is made according to a known technical solution from two types of threads containing a non-combustible twisted polyaramide thread. The non-combustible outer layer is made of fire-resistant wool fibers containing 8% potassium fluorozirconate by weight of the yarn with the addition of 20% twisted polyaramide yarn, and the inner layer is twisted wool fiber. In this case, the ratio of the incombustible component and the fibers of the combustible component in the fabric is 3: 1, respectively. Surface density 290 g / m ²

The results of testing fabric samples according to examples 1-7 are shown in tables (1-4). The device of a multilayer fire-resistant signal fabric with the declared parameters (examples 1-4) provides fire resistance and a high brightness coefficient, as well as the ability to produce on weaving machines of various types without equipment downtime due to breakage of threads and output of defective fabric. Fire resistance and brightness are retained after sun exposure, multiple washings and dry cleanings. Chromaticity coordinates comply with the requirements of GOST 12.4.281-2014. The proposed fabric can be used in the manufacture of protective clothing because provides comprehensive protection of a person from the effects of fire in conditions of insufficient visibility and withstands repeated processing.

Claims (5)

1. Multilayer fire-resistant signal fabric made of two types of threads and containing a non-flammable twisted polyaramide thread, characterized in that the interlacing of the threads in the layers of the fabric is different and is made by alternating the threads of the warp of the upper layer with the threads of the base of the lower layer, the upper layer of the fabric is made of untwisted polyester textured threads with an oxygen index of 28-30% linear density from 11 tex to 25 tex and coated with a fluorescent dye, the lower layer of the fabric is made of polyaramide yarns with an oxygen index of 28-30% linear density from 5.5 × 2 tex to 18 × 2 tex , the connection of the layers is made in a top-down manner, while the polyester threads are crumpled in the plane of the fabric surface until the diameter increases by 2.0–2.5 times, and the filling of the upper layer of the fabric with polyester threads is 0.3–0.5. 2. The multilayer fire-resistant signal fabric according to claim 1, characterized in that the weave is made by alternating the warp threads of the upper layer with the warp threads of the lower layer 2: 1, 2: 2, 1: 1 and 1: 2. 3. Multilayer fire-resistant signal fabric according to claim 1, characterized in that the weave of the upper layer is made on the basis of 2/2 twill, the weave of the lower layer is made on the basis of 2/2 twill. 4. Multilayer fire-resistant signal fabric according to claim 1, characterized in that the weave of the upper layer is made on the basis of satin 8/3, the weave of the lower layer is made on the basis of atlas 4/1. 5. Multilayer fire-resistant signal fabric according to claim 1, characterized in that the weave of the upper layer is made on the basis of 8/5 satin, the weave of the lower layer is made on the basis of atlas 4/1.

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