UA78440C2 - Composition biocomponent fiber with high color saturation and material of buck type made of it - Google Patents

Abstract

A conventional sea-island type composite fiber and its suede-like fabrics have poor color strength, and thus have problems such as an increase of a manufacturing cost and environmental contamination since they require a long time dyeing at a high concentration upon making the suede-like, fabrics. Further, they have a problem that the washing fastness and light fastness are low due to the use of a large amount of a dye.

Description

Description of the invention

The present invention relates to an island-in-the-sea composite bicomponent fiber having very high color saturation and suede-like materials made therefrom. More particularly, the present invention relates to an island-in-a-sea composite bicomponent fiber having very high color saturation (dyeability) due to the co-monomers content of the island component, and suede-like materials made therefrom and containing threads, some or all of what does this fiber consist of.

Influenced by recent trends, increasing market demands for higher quality products, as well as animal welfare concerns, the production and consumption of suede-like materials made from composite bicomponent fiber "islands in the sea" , is growing faster every day, and the areas of use of such fiber are also becoming more and more diverse.

Suede was first obtained by treating animal skins and was used to make high-quality gloves, women's shoes, etc. However, natural suede could not be produced in large quantities, since the raw material for its production is animal skin, and the number of animal heads is limited; in addition, the slaughter of animals leads to adverse phenomena, for example, to environmental pollution.

In addition, chamois was a material that was difficult to achieve widespread consumption due to its very high price due to the high costs caused by the above-described manufacturing process procedure, which had to be added to the price of the final product. Such natural suede also had the disadvantage that it was very difficult to store it when supplied for the manufacture of clothing, as it was difficult to wash with water even when supplied in large quantities.

However, the development of synthetic fibers served as a turning point, and their use significantly covered this lack of natural suede. This means that with the development of synthetic fibers, it became possible to manufacture suede-type products at a lower cost. p 29 The use of synthetic fibers made it possible to produce suede-like products in mass batches, Ho) caused less environmental pollution, did not require the slaughter of animals, suede-like materials were easy to process, as they were very easy to wash with water, and it became possible to dye them in different colors.

Such suede-type products, which are made with the use of synthetic fibers, began to be widely used in various types of furniture, in products for furnishing interiors, for example, for curtains, etc. and also in clothes. Recently, there has been a trend of using them also in the arrangement of car interiors, "due to the fact that their ability to paint and color durability have been significantly improved. Recently, suede-type materials have been especially widely used in clothing, women's toiletry items, as well as weekend M jumpers, coats, etc. Gee)

Such suede-type fabrics or knitted materials (hereinafter referred to as "suede-type materials") in which

zo use a synthetic fiber, can be made by using elementary threads of low linear density, which are obtained directly from the melt formation of composite fibers of a separate type or a composite bicomponent fiber of the "island in the sea" type. But suede-type products were characterized by the fact that the pile of fibers of low linear densities were combed on the surfaces, which is why it is most appropriate to manufacture suede-type products by using the composite bicomponent fiber C of the "islands in the sea" type in order to reveal this characteristic feature more effectively. c However, the composite bicomponent fiber of the "islands in the sea" type had a drawback, which was that it had a low dyeability. This means that even if the same amount of dye was used to dye it, the island-in-the-sea composite bicomponent fiber, which had a very large surface area, was dyed in a much lighter color than the usual one-comp onent fiber. Composite bicomponent fiber based on complex polyester also had the same drawback 49. To overcome this drawback, 7 usually used a method of dyeing artificial materials such as suede, made of composite

Ge | bicomponent fiber of the "islands in the sea" type, in a dye bath of high concentration for a long period of time. e However, this method of dyeing has a disadvantage, which is that the amount of used dye "iz" 20 increases too much, which leads to an increase in the cost of products and, at the same time, is associated with another disadvantage, which is because the possibility of environmental pollution increases. c In addition, due to the use of a large amount of dye, the resistance of the color of the finished product to washing and light is reduced.

In addition, to overcome the disadvantage of the composite bicomponent fiber of the "islands in the sea" type, which is low color saturation during dyeing, a method of introducing a pigment, for example, carbon black, is used

GF) into an island component of a composite bicomponent fiber of the "islands in the sea" type. In this case, additional equipment is required, including a side feeder, etc., and the production of the brood mix for separate use, which makes the process more complicated. In addition, there is another drawback, which is that if the diameter of the island component is equal to or smaller than the diameter of the pigment particles, the pigment cannot be introduced into the island component.

These and other distinctive features, aspects and advantages of the optimal implementation of this invention are more fully presented in the following detailed description with references to the attached drawings, which show: in Fig. 1 - a photograph obtained on a scanning electron microscope, which shows a cross section of a composite o-component fiber of the "island in the sea" type according to the present invention; because in Fig. 2 is a photo obtained on a scanning electron microscope, which shows a cross-section of a suede-type material made of a composite bicomponent fiber of the "islands in the sea" type according to this invention; Fig. 3C is a scanning electron microscope photograph showing a surface view of a suede-like material made of a composite bicomponent island-in-the-sea fiber (stretched complex thread) according to the present invention.

The present invention creates an island-in-the-sea composite bicomponent fiber that has very good color saturation without excessive shrinkage, which is obtained by properly modifying the polymer that has the ability to form the island component of the 7/0 island-in-the-sea composite bicomponent fiber. More specifically, the present invention creates an island-in-the-sea composite bicomponent fiber based on polyester, which has a color saturation enhancement factor of greater than 1095, a weight loss rate difference of less than 1095, and boiling water shrinkage (drawn complex thread) which is 5-1595 compared to the usual "islands in the sea" type composite bicomponent fiber. In addition, the present invention creates suede-like materials that have a very good 7/5 Color saturation by using the "island-in-the-sea" type composite bicomponent fiber islands in the sea", which has a very good color saturation, as part or half composition of a complex thread for the production of fabrics or knitted materials.

In order to achieve the above objective, a composite bicomponent fiber of the "islands in the sea" type has been created, which has a very good color saturation, according to the present invention, and contains: an island component, which consists mainly of polyethylene terephthalate, and the linear density of the elementary filament is 0.001 -0.5 denier (0.0001-0.056 tex); and a marine component that consists of an alkali-soluble complex polyester copolymer in which the island component contains a diol co-monomer of the chemical structural formula (I) and/or a diol co-monomer of the chemical structural formula (II) contained therein: rat () with

Be - o

I'm Cupcakes Ky

KE Fr

TC « okary sts: and sons from (I) with p. ШШ ШЕ ee and Z de K. and B" - alkyl groups with 1-3 carbon atoms,

X is an aliphatic ring with 5-8 carbon atoms. -

In addition, chamois materials of the present invention have been created in which some or all of the thread portions constituting the chamois materials are ultrafine yarns having a linear unit thread density of 0.001-0.5 denier (0.0001-0.056 tex) which contain a diol co-monomer with the chemical structural formula (I) and/or a diol co-monomer with the chemical structural formula (II), which are contained in polyethylene terephthalate, which is the main component. This invention is described in more detail below. First of all, the composite two-component fiber of the "island in the sea" type according to the present invention consists of a resin that has the ability to form a fiber as an island component, and a resin that is easily soluble in alkali, which is a marine component. But this invention differs in that the resin, which is an island component, is modified to improve the color saturation of the composite - bicomponent fiber of the "island in the sea" type. o More specifically, the island component according to the present invention contains a diol co-monomer with the chemical structural formula (I) and/or a diol co-monomer with the chemical structural formula (II), copolymerized t" (contained) in polyethylene terephthalate, which is the main component: o" i t () o . i SER PA z

F. KE kovu terte tnyh I zeulkh znakh (0 60 where K. and B" - alkyl groups with 1-3 carbon atoms,

X is an aliphatic ring with 5-8 carbon atoms.

In the case when the diol co-monomer with the chemical structural formula (I) and the diol co-monomer with the chemical structural formula (II) are contained together in the island component, and the content of the diol co-monomer with the chemical structural formula (I) is preferably 0.5-10.O0mol. because of the total content of the island resin component, and more preferably - 0.5-3.0mol.bo, the content of the diol co-monomer is 1.0-6.0mol.bo from the amount of ethylene glycol alone.

If the content of the diol co-monomer is greater than 10.00mol.9o, then the shrinkage of the stretched composite bicomponent fiber of the "island in the sea" type increases greatly, thus worsening the softness to the touch and the appearance of the finished product. If this content is less than O.Bmol.9o, then the effect of very good color saturation during painting may be insufficient.

The content of the diol co-monomer with the chemical structural formula (II) is preferably 0.5-15.O0mol.bo of the total content of the island resin component, more preferably - 0.5-5.O0mol.bo. The content of the diol co-monomer is 1.0-10.Omol.oo from the amount of only ethylene glycol. 76 If the diol co-monomer content is greater than 15.00mol.9o, then the shrinkage of the elongated composite bicomponent fiber of the "island in the sea" type is greatly increased, and thus does not provide the characteristic appearance and quality to the touch of suede. If this content is less than 0.5 mol.bo, then the effect of very good color saturation will not be achieved during painting.

At the same time, if the island component contains only a diol co-monomer with the chemical structural formula 7/5 (1) or only a diol co-monomer with the chemical structural formula (II), then the amount of the diol co-monomer with the chemical structural formula (I) or the diol co-monomer with chemical structural formula (II) should preferably be 1.0-20.00mol.bo. If this amount is greater than 20.O0mol.bo, then the unusual quality, touch and appearance of suede-type materials may be impaired due to increased fiber shrinkage. If the content is less than 1.00mol.bo, then the effect of very good color saturation is not achieved during dyeing.

Neopentyl glycol, 2,2-diethyl-1,3-propanediol, 2,2-ethylmethyl-1,3-propanediol or a similar compound can be used as the diol co-monomer with the chemical structural formula (I). 1,4-cyclohexanedimethanol, 1,3-cyclopentanedimethanol, 1,5-cycloheptandimethanol or a similar compound can be used as the diol co-monomer with the chemical structural formula (I).

The island component according to the present invention is produced by copolymerization of diol comonomers and sb comonomers used for the polymerization of polyethylene terephthalate, that is, ethylene glycol (EC) and terephthalic acid (TPA), and the linear density of the elementary threads is 0.001-0.5 denier (0.0001- 0.056 i) tex). If the linear density of elementary threads is more than 0.5 denier (0.056 tex), then the quality to the touch and the appearance of the finished product deteriorates. If it is less than 0.001 denier (0.0001 tex), then the production of the thread and the dissolution of the marine component are complicated. The marine component according to the present invention is preferably a copolymer of a complex polyester, which is ionic in nature and easily dissolves or decomposes easily in an alkaline solution, for example, in sodium hydroxide. -

The island-in-the-sea composite bicomponent fiber according to the present invention can be produced by the combined formation of the above-described island component and the sea component, using a conventional device for the combined formation of the island-in-the-sea bicomponent fiber, and their subsequent drawing and winding . The mass ratio of the island component and the sea component is preferably 70:30, but this invention is not specifically limited to their mass ratio.

The island-in-the-sea composite bicomponent fiber of the present invention has a color saturation enhancement factor of greater than 1095, as determined or estimated by the method described below, a difference in mass reduction rates of less than 10595, and boiling shrinkage water, which is 5-1595 shsh s, in the stretched state. The melting point of the island component remaining after the dissolution of the marine component is 220-24026. ;" The composite bicomponent fiber of the "islands in the sea" type according to the present invention has a structure in which the chain of the resin island component is bulky, because the island component contains (copolymerized) a diol co-monomer with the chemical structural formula (I) and/or a diol co-monomer with the chemical structural formula (II). Thus, the fiber is dyed in a much denser color than conventional composite fibers under the same dyeing conditions, including the use of the same dye. The suede-type material of the present invention can be produced by fabric production using the islands-in-the-sea composite bicomponent fiber of the present invention as some or all of the warp and weft, or by producing knitted materials using a composite o bicomponent fiber of the "island in the sea" type according to the present invention as some or all parts of the knitting thread; further dissolution and removal of the marine component from the materials by treating the materials with an aqueous alkali solution; dyeing materials and combing or chipping them.

The suede-like materials thus produced in accordance with the present invention include an ultrafine yarn having a linear density of 5 denier (0.556 tex) which contains some or all of the complex yarn components of the iF) material and is made from a diol co-monomer having the chemical structural formula (I) and /or diol co-monomer with the chemical structural formula (II), which are contained in polyethylene terephthalate, which is the main component of BO and II

Z i SER PA b5 KE kovu terte tnyh I zeulkh znakh (0 where K. and B" - alkyl groups with 1-3 carbon atoms, 2 X - an aliphatic ring with 5-8 carbon atoms.

Suede-type materials of the present invention include fabrics, warp knits, knitted fabrics, and the like.

According to the present invention, various physical properties of the composite bicomponent fiber of the "island in the sea" type were evaluated or measured using the techniques described below.

Coefficient of increase in color saturation (color saturation)

Color saturation was evaluated using the color saturation enhancement factor. First, the conventional island-in-the-sea composite bicomponent fiber consisting of polyethylene terephthalate with an unmodified island component and the island-in-the-sea composite bicomponent fiber of the present invention were treated with an aqueous solution of sodium hydroxide, respectively, to dissolve and remove of the marine component from the composite fiber, and only the island component was separated and extracted.

The island component (hereafter island component A) of the conventional island-in-the-sea composite bicomponent fiber and the island component (hereafter island component B) of the island-in-the-sea composite bicomponent fiber according to the present invention were extracted as described above, respectively dyed in a bath (each separately) during ЗОхв. at a temperature of 1302C with TEKABIYA VI ASK MAMU dye, a mixed dye produced by the Sira Zresiayu Spetis company, with a concentration of 1-Zmas.uo from the mass of the fiber to be dyed; then the painted island components were dried for 24 hours. at room temperature; after which the value of K/5 index of island component A and island component B at a wavelength of bbOnm was determined on a computer colorimeter comparing colors with the Zresigayaz 600 model standard of the company

OBaya Soiog Ipwigitepi Sotrapu. Then the obtained K/5 values of island component A and island component B were substituted into the following equation to calculate the coefficient of increase in color saturation. Gee)

Each of the K/5 values was a value measured 10 times and averaged.

Coefficient of increase in color saturation (90) - zve B KN VYA p

A skein of thread was prepared by keeping (a sample of) a composite bicomponent fiber of the "islands in the sea" type at room temperature for more than one hour, and then winding 10 turns on a winder under a tension corresponding to a certain linear density multiplied by 1/10g. The prepared skein was subjected to an initial load corresponding to a certain linear density multiplied by 1/25g, and a static

With a load corresponding to a certain linear density multiplied by 2 g, the length (I 0) was determined. Then the skein was subjected to heat treatment for 15 minutes. in water at 1002C, dehydrated with blotting paper, left to dry indoors for 12 hours. Then again, the skein was subjected to an initial load corresponding to a certain linear density multiplied by 1/25g and a static load corresponding to a certain linear density multiplied by 2g, and the length was determined (I 4). The value of the measured length I 9 and I; were substituted into the following equation to calculate shrinkage in boiling water: c) c Shrinkage in boiling water (90) а g»

Melting point (2C) of the island component -i The melting point of the island component was measured with the sea component removed using a differential scanning calorimeter (0552). It should be noted that the temperature range was between room temperature and 2802C, and the rate of temperature increase was 202C per minute. The mass of the sample was 0.5 mg--0.2 mg. trip 20 Difference in mass reduction rates (905)

10-15 g of the island component were separated and extracted from the usual composite bicomponent (ze) fiber of the "island in the sea" type, consisting of polyethylene terephthalate with an unmodified island component, then the mass of the extracted island component (hereafter island component A) was reduced by immersing it in Imas.95 an aqueous solution of sodium hydroxide with a liquid ratio of 50 at a temperature of 2° 9590 and kept for 10 minutes, after which the mass of MU » island component A was determined (after reduction

GF! masses). The value of the mass MU of the island component A before the mass reduction and the mass M/o of the island component A after the mass reduction were substituted into the following equation to calculate the rate of decrease in the mass of the island o component A.

The rate of decrease in the mass of the island component A (95) is also 6 o renya pc,

SYA) What

Then, 10-15 g of the island component were separated and extracted from the composite bicomponent fiber of the "islands in the sea" type according to this invention, and the mass of the extracted island 65 component (hereinafter island component B) was reduced by immersing it in 1 wt.9o aqueous solution of sodium hydroxide with the ratio of liquid 50 at a temperature of 952C and kept for 10 minutes, after which the mass of MU in the island component B was determined (after mass reduction). The value of the mass of MU from the island component B before the mass reduction and the mass of Mu, the island component B after the mass reduction were substituted into the following equation to calculate the rate of mass reduction of the island component B.

The rate of decrease in the mass of the insular component B (95) is the same as sEdlclh.

The calculated mass reduction rates of island component A and island component B were substituted into the following equation to calculate the difference in mass reduction rates.

The difference in the rate of mass reduction (90) is the result: the peak is slaked BATH with VC. pe s ssh 00 0 pc y EE KE aty Ok V NNuen rek neneY zhk

An island-in-the-sea composite bicomponent fiber of the present invention is obtained, which has very good color saturation without excessive shrinkage, because the fiber-forming polymer representing the island component is modified into diol comonomers and thus it can have a richer color, which is difficult to achieve using a conventional composite bicomponent fiber of the "islands in the sea" type, based on complex polyester. Accordingly, problems related to, for example, increased production costs due to excessive dye consumption during dyeing, environmental pollution, resistance to washing, light exposure, etc., can be solved.

In addition, the color saturation of the finished products can be significantly increased when materials such as suede are manufactured.

The present invention is further explained in more detail by comparing embodiments of the present invention with comparative examples. However, the present invention is not limited to these examples. at

Example 1

A composite bicomponent fiber of the "islands in the sea" type (drawn complex thread with a linear density of 75 denier (8.34 tex) containing 24 elementary threads) was produced by using as a marine component an ionic copolymer of a complex polyester soluble in an aqueous solution of sodium hydroxide, and as island ("c") component - a copolymer of a complex polyester containing mol.bu neopentyl glycol and 2mol.bo "t 1,4-cyclohexanedimethanol, copolymerized (contained) in polyethylene terephthalate, which is the main component. At this time, the number of island components in one elementary thread was 36, the mass ratio of the island component to the marine component was 70:30, and the linear density of the elementary thread of the island component was brought to 0.061 denier (0.0067 tex). The composite two-component fiber of the "islands in the sea" type produced in this way was used as a base and warp for the production of fabrics and - satin weave. Fabrics were treated with an aqueous solution of sodium hydroxide to dissolve the marine component, dyed and combed, thus obtaining suede-like fabrics. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table. "

Example 2

The composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in Example 1, except that a complex polyester copolymer containing bmol.bo neopentylglycol and mol. » 1,4-cyclohexanedimethanol copolymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table. - and Example C o Composite bicomponent fiber of the "islands in the sea" type and materials of the suede type were produced in the same way and under the same conditions as in example 1, except that as an island component in the combined formation, a copolymer of complex polyester containing 5mol.bo 2,2-diethyl-1,3-propanediol and 50 1Omol.bo 1,5-cycloheptandimethanol, co-polymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite two-component fiber type "islands in the sea" c2 are shown in the table.

Example 4

The island-in-a-sea composite bicomponent fiber and suede-like materials were produced in the same manner and under the same conditions as in Example 1, except that the island component in the combined

Gee! a complex polyester copolymer containing 5 mol. of 2,2-diethyl-1,3-propanediol and mol. 1,5-cycloheptandimethanol, co-polymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table. 60 Example 5

Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in example 1, except that a complex polyester copolymer containing 5 mol.bo was used as the island component in the combined molding neopentyl glycol and 1Omol.Zo 1,4-cyclohexanedimethanol, co-polymerized (contained) in polyethylene terephthalate, which is the main 65 component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are given in the table.

Example 6

Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in Example 1, except that a complex polyester copolymer containing TOmol.bo was used as the island component in the combined molding of neopentyl glycol and 15 mol.Zo of 1,4-cyclohexadimethanol, co-polymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table.

Example 7 70 Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same manner and under the same conditions as in Example 1, except that a complex polyester copolymer containing O.5mol.bo neopentyl glycol and 0O.bmol.Zo 1,4-cyclohexanedimethanol, co-polymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown /5 in the table.

Example 8

A composite bicomponent fiber of the "islands in the sea" type (an elongated complex thread with a linear density of 75 denier (8.34 tex) containing 24 elementary threads) was produced by using as a marine component an ionic copolymer of a complex polyester soluble in an aqueous solution of sodium hydroxide, and as island 2 o Component - a copolymer of a complex polyester containing Tmol. U5 neopentyl glycol and /2 mol. o 1,4-cyclohexanedimethanol, copolymerized (contained) in polyethylene terephthalate, which is the main component. At the same time, the number of island components in one elementary thread was 36, the mass ratio of the island component to the marine component was 70:30, and the linear density of the elementary thread of the island component was brought to 0.061 denier (0.0067 tex). The composite two-component fiber of the "islands in the sea" type produced in this way was used for the production of fabrics with a knitted weave. Fabrics were treated with an aqueous solution of sodium hydroxide to dissolve the marine component, and) dyed and combed, thus obtaining suede-type materials (knitted materials). Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table.

Example 9 o z Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in example 8, except that a complex polyester copolymer was used as an island component during combined - forming. containing bmol.bo of neopentyl glycol and mol. " 1,4-cyclohexanedimethanol copolymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table. Cha

Example 10

Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in Example 8, except that a complex polyester copolymer containing 5 mol.bo was used as the island component in the combined molding 1,2-diethyl-1,3-propanediol and "

LOmol.lo of 1,5-cycloheptandimethanol, co-polymerized (contained) in polyethylene terephthalate, which is with the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are shown in the table. from Example 11

Composite bicomponent fiber of the "islands in the sea" type and suede-type materials were produced in the same way and under the same conditions as in example 1, except that a complex polyester copolymer containing 15 mol was used as the island component in the combined -I formation .because of 1,4-cyclohexanedimethanol copolymerized (contained) in polyethylene terephthalate, which is the main component. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are given in the table. their Comparative example 1

A composite bicomponent fiber of the "islands in the sea" type (drawn complex linear thread with a density of 75 denier (8.34 tex) containing 24 elementary threads) was produced by using as a marine component an ionic copolymer of a complex polyester soluble in an aqueous solution - sodium hydroxide , and as an island component - polyethylene terephthalate (unmodified).

At the same time, the number of island components in one elementary thread was 36, the mass ratio of the island component to the sea component was 70:30, and the linear density of the elementary thread of the island component was brought to 0.061 denier (0.0067 tex). Made in this way composite

F) two-component fiber of the "islands in the sea" type was used as a base and warp to produce, in this way, a fabric of satin weave. Fabrics were treated with an aqueous solution of sodium hydroxide to dissolve the marine component, dyed and combed, thus obtaining suede-like fabrics. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are given in the table.

Comparative example 2

A composite bicomponent fiber of the "islands in the sea" type (an elongated complex thread with a linear density of 75 denier (8.34 tex) containing 24 elementary threads) was produced by using as a marine component an ionic copolymer of a complex polyester soluble in an aqueous solution of sodium hydroxide 65 , and as an island component - polyethylene terephthalate (unmodified).

At the same time, the number of island components in one elementary thread was 36, the mass ratio of the island component to the marine component was 70:30, and the linear density of the elementary thread of the island component was brought to 0.061 denier (0.0067 tex). The composite bicomponent fiber of the "islands in the sea" type produced in this way was used for the production of fabrics with a knitted weave. Fabrics were treated with an aqueous solution of sodium hydroxide to dissolve the marine component, dyed and combed, thus obtaining suede-like fabrics. Various physical properties of the composite bicomponent fiber of the "island in the sea" type are given in the table. ! COMPOSITE bicomponent fiber type islands in the sea" color (95) mass (95) boiling point (90) and component (C) with

Before 100000050000001111116011111110901

Pred /1111105011011011111189000110112v jus 2 pcs o example 1 Ge) sh-I Z 2 1 OLP 2 6 example 2 «c)

Claims (12)

Formula of the invention "t" 1. A composite two-component fiber of the "islands in the sea" type, which contains an "island" component consisting mostly of polyethylene terephthalate, the linear density of the elementary thread of which is 0.0001-0.056 tex, and a "sea" component consisting of a copolymer of complex polyester, easily soluble in alkali, where the "island" component is modified with a diol of the formula (I) and/or a diol of the formula (II) M. g" in HO-SHO-X-SHO-OH, (II) where K. and B" - alkyl groups with 1-3 carbon atoms, sh- X - an aliphatic ring with 5-8 carbon atoms. Go! 2. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which differs in that the content of the diol of formula (I) is 0.5-10.0 mol. In, and the content of diol of formula (II) is 0.5-15.0 mol. 905 relative to the "island" component. there are 20 of them 3. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which differs in that the content of diol of formula (I) is 0.5-3.0 mol. Zo, and the content of diol of the formula (II) is 0.5-5.0 mol. 90 relative to me, the "island" component. 4. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which differs in that the content of diol of formula (I) is 1.0-20.0 mol. 95 relative to the "island" component. 59 5. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which is characterized by the fact that the content of diol HF) of formula (II) is 1.0-20.0 mol. 95 relative to the "island" component. 6. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which differs in that the diol of the formula (I) is neopentyl glycol, 2,2-diethyl-1,3-propanediol or 2,2-ethylmethyl-1, 3-propanediol. 7. Composite two-component fiber of the "islands in the sea" type according to claim 1, which differs in that the diol of formula 60 (I) is 1,4-cyclohexanedimethanol, 1,3-dcyclopentanedimethanol or 1,5-cycloheptandimethanol. 8. Composite bicomponent fiber of the "islands in the sea" type according to claim 1, which is characterized by the fact that it provides a color saturation enhancement factor of more than 10,965. 9. Composite two-component fiber of the "islands in the sea" type according to claim 1, which differs in that the shrinkage during boiling of the stretched complex thread is 5-15 90. 10. Composite two-component fiber of the "island in the sea" type according to claim 1, which is characterized by the fact that the melting point of the "island" component, which remains after the dissolution of the "sea" component, is 220-240 26. 11. Suede-type material, in which some or all parts of the complex thread of which it consists, are ultrafine elementary threads with a linear density of 0.0001-0.056 tex, which include the main component polyethylene terephthalate, modified with a diol of the formula (I) and/or diol of formula (II) М. X is an aliphatic ring with 5-8 carbon atoms. 12. The material of the suede type according to claim 11, which is characterized by the fact that it is a woven material, a warp-knitted material or a fabric with a knitted weave. c 6) "c) " " (ee) and - - with . and? -I (ee) sh» sh» (42) ime) 60 b5