KR20190117668A - Textile fabrics and coveralls made of them - Google Patents

Abstract

A textile fabric is provided comprising staple fiber yarns made from a staple fiber blend, the blend comprising meta-aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers. The textile fabric is used in the manufacture of work clothes.

Description

Textile fabrics and coveralls made of them

The present invention relates to textile fabrics and work clothes made therefrom.

Textile fabrics are known. Fabrics of this type must be particularly heat protective and must also exhibit sufficient mechanical properties, for example sufficient tear strength.

US 2011/0138523 A1 discloses a fabric that is heat protective, flame protective and electric arc protective for use as a single layer of protective clothing for a wearer, the fabric being fabricated from warp warp and weft yarns, and from the wearer. A fabric face facing away and a fabric face facing the wearer, wherein the warp and weft yarns comprise 8-33 wt% meta-aramid staple fibers, 65-90 wt% para-aramid staple fibers, and 2 wt% electrostatic A blend of resistant staple fibers, wherein the weft yarns and warp yarns are identical, and the fabric provides ablative thermal protection for both sides. In the example, a fabric having a twill K2 / 1Z structure and a basis weight of 230 g / m 2 has a warp tear resistance of 67.87 N and weft tear resistance of 34.4 N, measured using the ISO 13937-1: 2000 test procedure. Indicates.

EP 1740746 B1 discloses a heat and flame resistant fabric for use as a single layer or outer layer of protective garments. The fabric includes fibers having a blend of 60-90 wt% meta-aramid staple fibers and 5-40 wt% para-aramid fibers. The fabric does not comprise polylactide staple fibers.

WO 02/40755 A2 discloses a refractory corespun yarn comprising a core of high temperature resistant continuous inorganic filaments and first and second sheaths of staple fibers. The first sheath comprises natural and synthetic staple fibers having one or more flame retardant fibers. The staple fibers of the second sheath are selected from natural staple fibers or synthetic staple fibers. WO 02/40755 A2 does not mention blends of meta-aramid staple fibers and para-aramid staple fibers with polylactic acid staple fibers.

The staple fiber composition DuPont ^™ Nomex ^® IIIA is also known to consist of 93% Nomex ^® m-aramid staple fibers, 5% Kevlar ^® p-aramid staple fibers, and 2% antistatic staple fibers. According to DuPont's Internet presentation, fabrics made with the staple fiber composition DuPont ^™ Nomex ^® IIIA meet the NFPA 1975 standard for firefighter's station wear and are resistant to wear and tear.

However, there is a continuing need for thermally protective textile fabrics with better mechanical properties, in particular high resistance to tearing and abrasion, which are used in the production of workwear in which the fabric should have as high wear resistance and tear strength as possible. This is because the fabric should be able to be worn for as long as possible. In addition, there is a continuing need for heat-protective textile fabrics with better wearing comfort, because the fabric often wears out during high physical fatigue, which should not be further increased by the uncomfortable feeling caused by the workwear.

Accordingly, the problem underlying the present invention is to provide a fabric that exhibits higher tear strength and higher comfort than in the garments produced, in particular the workwear.

The problem is solved by a textile fabric comprising staple fiber yarns made from a staple fiber blend, the blend comprising meta-aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers.

Surprisingly, the textile fabrics according to the invention are more resistant to wear and tear than comparable textile fabrics made of staple fiber yarns made from staple fiber blends made of a staple fiber mixture consisting of meta-aramid staple fibers, para-aramid staple fibers and antistatic staple fibers. Higher resistance to. Thus, a garment comprising the textile fabric according to the invention is capable of wearing for a longer time before it is damaged.

Further higher values for wear and tear resistance of textile fabrics according to the present invention are staple fiber yarns made from a staple fiber mixture consisting of meta-aramid staple fibers, para-aramid staple fibers and antistatic staple fibers. A lower basis weight of the textile fabric can be obtained when compared to the basis weight of the fabric fabric of comparison. Thus, a garment comprising a textile fabric according to the invention can be worn with a higher wearing comfort than a garment comprising a textile fabric of comparison. Alternatively, a garment comprising the textile fabric according to the invention, wherein the basis weight of the textile fabric has been increased to the basis weight value of the textile fabric to be compared is the same comfort as the garment comprising the textile fabric to be compared but for much longer time. It can be worn because the resistance to wear and tear of garments with the textile fabrics of the present invention is much more increased.

Unlike meta-aramids and para-aramids, polylactic acid is not inherently heat and flame resistant, but surprisingly, the textile fabrics according to the invention meet the minimum requirements with regard to radiant heat, convective heat and contact heat.

Finally, if the garment comprising the textile fabric according to the invention is to be discarded, the polylactic acid component of the textile fabric can be completely recycled, since the polylactic acid can be completely biodegraded to produce compost. Compost can be used as a substrate for corn growth. Corn may be fermented with lactic acid, which may be polymerized with polylactic acid to produce polylactic acid staple fibers. Accordingly, the textile fabrics according to the invention contain renewable components.

Within the scope of the present invention, the term “staple fiber” means a limited length of fiber obtained by cutting or crushing filament yarns.

Within the scope of the present invention, the term "meta-aramid staple fiber" refers to staple fibers obtained by cutting or crushing meta-aramid filament yarns, and the term "meta-aramid" refers to meta-orientation with meta-oriented aromatic diamines. Refers to a polymer obtained by polycondensation of a dicarboxylic acid halide, wherein the polymer represents a repeating unit having an amide bond, preferably at least 85% of the amide bond is located in a meta-oriented position of the aromatic ring.

Within the scope of the present invention, the term "para-aramid staple fibers" refers to staple fibers obtained by cutting or crushing para-aramid filament yarns, and the term "para-aramid" refers to para-oriented with para-oriented aromatic diamines. Means a polymer obtained by polycondensation of a dicarboxylic acid halide, wherein the repeating unit of the polymer has an amide bond, preferably at least 65%, more preferably at least 95%, even more preferably of the amide bond Is at least 99%, most preferably 100% located in the para-oriented position of the aromatic ring.

Within the scope of the present invention, the term “aramid staple fiber” means staple fiber obtained by cutting or crushing aramid filament yarns. The term aramid means a polymer whose aromatic moieties are linked to each other by amide bonds. Aramids are generally synthesized by polycondensation of aromatic diamines and aromatic dihalides. Aramids can be used to form meta-aramid, para-aramid and aramid-copolymers such as copolymers [co-poly- (paraphenylene / 3,4'-oxydiphenylene terephthalamide)] (Technora®). Include.

Within the scope of the present invention, the term "polylactic acid staple fiber" refers to staple fibers obtained by cutting or crushing polylactic acid filament yarns, and the term "polylactic acid" means a polymer having a lactide repeat unit, which means " Polylactide ".

Within the scope of the present invention, the term “staple fiber blend” means an intimate mixture of meta-aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers, so that in each volume element of the staple fiber blend There is an equal weight ratio of para-aramid staple fibers to meta-aramid staple fibers to polylactic acid staple fibers. The adjacent mixture can be obtained, for example, by intermingling in air of meta-aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers.

Within the scope of the present invention, the term “staple fiber yarn” is used to describe meta- by any known method for producing staple fiber yarns, for example by open-ended spinning such as ring spinning or air-jet spinning. A yarn made from a staple fiber blend of aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers.

Within the scope of the present invention, the term "textile fabric" means a blend of staple fibers spun into yarns arranged in a specific fabric structure.

In a preferred embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend,

30-90 wt% meta-aramid staple fiber,

5 to 60 wt% of para-aramid staple fibers, and

5 to 40 wt% polylactic acid staple fibers.

In a more preferred embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend,

40-85 wt% meta-aramid staple fiber,

5-50 wt% para-aramid staple fiber, and

5 to 30 wt% polylactic acid staple fibers.

In the most preferred embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend,

50-85 wt% meta-aramid staple fiber,

10 to 40 wt% para-aramid staple fibers, and

5 to 25 wt% polylactic acid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, up to 95 wt% aramid staple fibers, preferably up to 90 wt% aramid staple fibers, more preferably up to 80 wt% aramid Staple fibers, or up to 70 wt% aramid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, at least 40 wt% of meta-aramid staple fibers, preferably at least 50 wt% of meta-aramid staple fibers, more preferably at least 60 wt% Meta-aramid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, up to 85 wt% meta-aramid staple fibers, more preferably up to 75 wt% meta-aramid staple fibers, or up to 65 wt% Meta-aramid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, at least 10 wt% of para-aramid staple fibers, preferably at least 20 wt% of para-aramid staple fibers, more preferably at least 30 wt% Para-aramid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, up to 50 wt% of para-aramid staple fibers, more preferably up to 40 wt% of para-aramid staple fibers, or up to 35 wt% Para-aramid staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, at least 10 wt% polylactic acid staple fibers, preferably at least 15 wt% polylactic acid staple fibers, more preferably at least 20 wt% polylactic acid Staple fibers.

In an embodiment of the textile fabric according to the invention, the blend is based on the weight of the blend, up to 35 wt% polylactic acid staple fibers, more preferably up to 30 wt% polylactic acid staple fibers, or up to 25 wt% poly Lactic acid staple fibers.

As mentioned above, the term "staple fiber" refers to a limited length of fiber obtained by cutting or crushing filament yarns. When staple fibers are obtained by shredding, the staple fibers exhibit a characteristic length distribution for the shredding technique applied, for example stretch shredding. Preferably, staple fibers are obtained by cutting the filament yarns into unitary lengths preset in the cutting device used. This produces staple fibers with a single length.

In a preferred embodiment of the textile fabric according to the invention, the single length of meta-aramid staple fibers is 30 to 140 mm, the single length of para-aramid staple fibers is 30 to 140 mm and the single length of polylactic acid staple fibers is 30 to 140 mm to be.

In a more preferred embodiment of the textile fabric according to the invention, the single length of the meta-aramid staple fibers is 30 to 130 mm, the single length of the para-aramid staple fibers is 30 to 130 mm and the single length of the polylactic acid staple fibers is 30 to 130mm.

In the most preferred embodiment of the textile fabric according to the invention, the single length of the meta-aramid staple fibers is 30 to 120 mm, the single length of the para-aramid staple fibers is 30 to 120 mm, and the single length of the polylactic acid staple fibers is 30 to 120 mm.

In a preferred embodiment of the textile fabric according to the invention, the linear density of meta-aramid staple fibers is 0.8-7 dtex, the linear density of para-aramid staple fibers is 0.8-7 dtex, and the linear density of polylactic acid staple fibers is 0.8-7 dtex.

In a more preferred embodiment of the textile fabric according to the invention, the linear density of meta-aramid staple fibers is 0.8-6 dtex, the linear density of para-aramid staple fibers is 0.8-6 dtex, and the linear density of polylactic acid staple fibers is 0.8-6 dtex.

In the most preferred embodiment of the textile fabric according to the present invention, the linear density of meta-aramid staple fibers is 0.8 to 5 dtex, the linear density of para-aramid staple fibers is 0.8 to 5 dtex, and the linear density of polylactic acid staple fibers is 0.8 to 5 dtex.

In a preferred embodiment of the textile fabric according to the invention, the blend adds up to 5 wt%, preferably 0 to 4 wt%, most preferably 0 to 3 wt% of antistatic staple fibers, based on the weight of the blend. It includes. Preferably, the antistatic staple fiber comprises polyester, carbon or steel or mixtures thereof as the antistatic fiber forming polymer.

In a preferred embodiment of the textile fabric according to the invention, the antistatic staple fibers have a length of 30 to 140 mm and a linear density of 0.8 to 7 dtex.

In a more preferred embodiment of the textile fabric according to the invention, the antistatic staple fibers have a length of 30 to 130 mm and a linear density of 0.8 to 6 dtex.

In the most preferred embodiment of the textile fabric according to the present invention, the antistatic staple fiber has a length of 30 to 120 mm and a linear density of 0.8 to 5 dtex.

Preferably, the meta-aramid staple fibers consist of a staple fiber blend which preferably represents crimps with crimp values in the range of 2 to 13 crimps per cm, more preferably 3 to 10 crimps per cm.

Preferably, the para-aramid staple fibers preferably consist of a staple fiber blend that exhibits crimps with crimp values in the range of 2 to 13 crimps per cm, more preferably 3 to 10 crimps per cm.

Preferably, the polylactic acid staple fibers consist of a staple fiber blend which preferably represents crimps with crimp values in the range of 3 to 13 crimps per cm, more preferably 5 to 10 crimps per cm.

In a preferred embodiment of the textile fabric according to the invention, the staple fibers are aramid staple fibers which exhibit a crimp value of 2 to 13 crimps per cm, preferably 3 to 10 crimps per cm, and 3 to 13 crimps per cm. It consists of a staple fiber blend comprising a polylactic acid staple fiber exhibiting a crimp value of, preferably 4 to 10 crimps per cm.

In a preferred embodiment of the textile fabric according to the invention, the meta-aramid staple fibers are preferably poly (meth-phenylene isophthal) spun from a solution comprising poly (meth-phenylene isophthalamide) in dimethyl acetamide. Amide) staple fibers, para-aramid staple fibers are poly- (p-phenylene terephthalamide) staple fibers or poly (p-phenylene-3,4'-oxydiphenylene terephthalamide) staple fibers, poly The lactic acid staple fiber is a staple fiber made of poly-L-lactic acid staple fiber or poly-D-lactic acid staple fiber, or a racemic mixture of poly-L-lactic acid and poly-D-lactic acid, or poly-L-lactic acid and Staple fibers made of a stereo complex of poly-D-lactic acid.

Macromolecules having the same chemical composition but different repeating units may form intermolecular complexes called stereo complexes. Stereo complex formation of polylactide occurs due to the non-covalent interaction of enantiomeric chains of poly-L-lactic acid (PLLA) and poly-D-lactic acid (PDLA), and exhibits higher thermal stability. Preferably, PLLA and PDLA are arranged differently within the stereo complex to form a crystal structure.

In a preferred embodiment of the textile fabric according to the invention, the yarns are made from the blend by ring spinning or air jet spinning.

The textile fabric according to the invention can in principle be any fiber network arranged in a specific fabric structure and adapted to form a garment.

Preferably, the textile fabric according to the present invention is a woven or knitted textile fabric.

Further, the textile fabric according to the present invention preferably has a twill or plain weave structure.

It is also preferred that the textile fabric according to the invention has a twill or plain weave structure comprising at least one warp system and at least one weft system, wherein the at least one warp system and the at least one weft system have a yarn having the same blend of staple fibers. Or a yarn having different blends of staple fibers.

Preferably, the basis weight of the textile fabric according to the invention is 50 to 400 g / m 2, more preferably 80 to 380 g / m 2 and most preferably 100 to 350 g / m 2.

Textile fabrics according to the invention of advantageous properties are transformed into garments produced using said textile fabrics. Such garments comprise one or more textile fabrics according to the invention. Due to the improved wear and peeling resistance, these garments are particularly suitable as work clothes. Thus, the use of such textile fabrics for making work clothes is also part of the present invention.

The invention is illustrated in more detail in the following non-limiting examples.

Example

Sample manufacture:

Example 1 (according to the invention)

a) staple  Preparation of Fiber Blends (Example 1)

Poly (p-phenyleneterephthalamide) staple fibers of type Twaron 1070 with 25 wt%, length of 40 mm, linear density of 1.7 dtex and crimp value of 4 to 8 crimps per cm,

TeijinConex T with a length of 50 mm, a linear density of 1.7 dtex, and a crimp value of 3 to 7 crimps per cm, spun from a solution comprising poly (meth-phenylene isophthalamide) in dimethyl acetamide, 65 wt% Poly (m-phenyleneisophthalamide) staple fiber of BL1 type, and

10wt%, 38mm length, 1.5dtex linear density, 38cN / tex tenacity, 40% elongation at break, 7 crimps per cm crimp value and 5.4% boiling water shrinkage Adjacent staple fiber blends, consisting of polylactic acid staple fiber “ingeo” obtained from RMB fiber AG (CH), were prepared by blending the staple fibers adjacently to the weight percentage.

b) staple  fiber Of yarn (Example 1)  Produce

From the staple fiber blend produced in step a), two Nm 40/1 staple fiber yarns were prepared. The two Nm 40/1 staple fiber yarns were burned to produce Nm 40/2 burnable staple fiber yarns.

c) woven fabric Of (Example 1)  Produce

From the Nm 40/2 combustible staple fiber yarn produced in step b), according to DIN EN ISO 7211-1, the twill weaving has two lifts and one downward in the Z-direction. Weaving fabrics exhibiting lowering were made, and both the warp thread and the weft thread consisted of staple fiber yarns produced in step b). The textile fabric consists of warp threads with a thread density of 191 threads / 10 cm and weft threads with a thread density of 182 threads / 10 cm. Thread density was measured according to DIN EN ISO 1049-2.

The basis weight of the woven fabric reached 202 g / m 2 and was measured according to DIN EN ISO 12127.

Comparative Example 1 CE1 )

a) comparison staple  Fiber blends ( CE1 ) Offer

Poly (p-phenylenetrephthalamide) DuPont ^™ Kevlar® staple fiber with a single length of 50 mm, linear density of 1.7 dtex, 5 wt%

Poly (m-phenyleneisophthalamide) DuPont ^™ Nomex® staple fiber having a 93 wt%, length of 50 mm, linear density of 1.7 dtex and crimp value of crimp per cm, and

A comparative staple fiber blend is obtained from DuPont (USA) under the tradename Nomex® IIIA, consisting of 2 wt%, antistatic staple fibers having a single length of 50 mm, linear density of 1.7 dtex.

b) comparison staple  Fiber yarn CE1 Manufacturing

From the Nomex® IIIA staple fiber mixture provided in step a), one Nm 60/1 staple fiber yarn and one Nm 60/1 staple fiber yarn were prepared. The two staple fiber yarns were twisted to produce Nm 60/2 burnable staple fiber yarns.

c) comparative weaving fabric Of (CE 1)  Produce

According to DIN EN ISO 7211-1 a comparative textile fabric was produced having a 2/1 Z structure, ie, twill weaving showing two upwards and one downwards in the Z-direction, and both the warp thread and the weft thread were step b). It consists of comparative flammable staple fiber yarns produced in The textile fabric consists of a warp thread with a thread density of 386 threads / 10 cm and a weft thread with a thread density of 244 threads / 10 cm. Thread density was measured according to DIN EN ISO 1049-2. The basis weight of the compared textile fabric reached 225 g / m 2 and was measured according to DIN EN ISO 12127.

Comparative Example 2 CE2 )

a) comparison staple  Fiber blends ( CE2 ) Offer

Twaron 1072 type poly (p-phenyleneterephthalamide) staple fiber having a 60 wt%, length of 50 mm, linear density of 1.7 dtex, and crimp value of 4 to 9 crimps per cm, and

TeijinConex YE5 spun from a solution comprising poly (meth-phenylene isophthalamide) in dimethyl acetamide, having a weight of 40 wt%, a length of 50 mm, a linear density of 1.7 dtex, and a crimp value of 3 to 7 crimps per cm. A comparative staple fiber blend, consisting of tangible poly (m-phenyleneisophthalamide) staple fibers, was prepared by blending the staple fibers adjacently to the weight percentage.

The manufacturing process b) of the staple fiber yarn of CE 2 and the manufacturing process c) of the woven fabric of CE 2 are carried out as in Comparative Example 1 (CE1).

Thread / 10 cm values for woven fabrics ranging from 188 warp-thread and 199 weft-thread were measured according to DIN EN ISO 1049-2.

The basis weight of the woven fabric reached 204 g / m 2 and was measured according to DIN EN ISO 12127.

Comparative Example 3 CE3 )

a) comparison staple  Fiber blends ( CE3 ) Offer

Twaron 1072 type poly (p-phenyleneterephthalamide) staple fiber having a 40 wt%, length of 50 mm, linear density of 1.7 dtex, and crimp value of 4 to 9 crimps per cm, and

TeijinConex YE5 spun from a solution comprising poly (meth-phenylene isophthalamide) in dimethyl acetamide, having 60 wt%, a length of 50 mm and a linear density of 1.7 dtex, and a crimp value of 3 to 7 crimps per cm. A comparative staple fiber blend, consisting of tangible poly (m-phenyleneisophthalamide) staple fibers, was prepared by blending the staple fibers adjacently to the weight percentage.

The manufacturing process b) of the staple fiber yarn of CE 3 and the manufacturing process c) of the woven fabric of CE 3 are carried out as in Comparative Example 1 (CE1).

Thread / 10 cm values for woven fabrics ranging from 188 warp-thread and 179 weft-thread were measured according to DIN EN ISO 1049-2.

The basis weight of the woven fabric reached 204 g / m 2 and was measured according to DIN EN ISO 12127.

For clarity, the staple fiber blend compositions of Example 1 and Comparative Examples (CE1 to CE3) are shown in Table 1.

TABLE 1

Way

The properties of the woven fabric and the comparative woven fabric were measured as follows:

The tensile strength [N] and elongation at break [%] of both the woven fabric and the comparative woven fabric according to the invention are measured according to DIN EN ISO 13934-1,

The tensile strength [N] of the staple fiber yarns according to the invention is measured according to DIN EN ISO 13934-1,

The tear strength [N] of both the woven fabric and the comparative woven fabric according to the invention is measured according to DIN EN ISO 13937-2,

The peeling resistance of both the woven fabric and the comparative woven fabric according to the invention was measured according to DIN EN ISO 12945-2 after a certain number of cycles, where evaluation 1 indicates the lowest peeling resistance and evaluation 5 the highest peeling resistance Indicates,

Wear resistance of both the woven fabric and the comparative textile fabric according to the invention were measured according to DIN EN ISO 12947-2 after a certain number of cycles until the two threads in the sample were completely destroyed, three samples each being Was calculated to calculate the arithmetic mean value of the three samples.

The convective heat of the woven fabric according to the invention is measured according to ISO 9151 until the heat transfer index t _HTI [s], i.e. a calorimeter installed at a particular distance above the textile fabric, measures a temperature increase of 24 ° And the textile fabric was arranged at a distance above the Bunsen burner which burned at 80 kW / m 2,

The radiant heat of the woven fabric according to the invention is measured according to ISO 6942, t _{24 ° C, 20 kW / m 2} [s] and t _{24 ° C, 40 kW / m 2} [s], ie a temperature of 24 ° C on one side of the textile fabric The time in seconds to measure the increase was measured, and the textile fabric was arranged at a calibrated distance from the radiant heat source radiated at 20 kW / m 2 or 80 kW / m 2, and then, in operation, of the radiant heat at which a second degree burn was expected. To simulate breakthrough times,

The heat of contact of the woven fabric according to the invention is measured according to ISO 12127, the threshold time t _threshold [s], i.e. seconds until a calorimeter installed under the textile fabric at a certain distance measures a temperature increase of 10 ° C. Expressed in units of time, the textile fabric being in contact with a drum having a temperature of 250 ° C.,

Heat shrinkage of the woven fabric at 180 ° C. in [%], and

Heat shrinkage of the woven fabric at 250 ° C. in [%].

Standard deviations were provided for tensile strength [N], elongation at break [%] and tear strength [N], each of the five samples measured in the warp and weft directions.

Experiment result

Experiment 1

In Experiment 1, two woven fabrics (Example 1 and Comparative Example 1 according to the invention) were tested to compare their properties. The results are shown in Table 2.

TABLE 2

The following conclusions can be drawn from Table 2:

The wear resistance (120,000 cycles) of the woven fabric according to the invention is 33-42% higher than the wear resistance (70,000 to 80,000 cycles) of the comparative woven fabric.

Warp tear resistance, ie the warp tear strength (72.2N) of the woven fabric according to the invention is 33% higher than the warp tear strength of the comparative woven fabric (54.4 N), and the weft tear strength (75.9) of the woven fabric according to the invention N) is 39% higher than the weft tear strength (54.7N) of the comparative woven fabric.

Higher resistance to tearing and abrasion of the woven fabric according to the invention is obtained with a fabric basis weight of 202 g / m 2, ie with a fabric basis weight 10% lower than the fabric basis weight of the comparative woven fabric (225 g / m 2).

While the woven fabric according to the present invention contains 10 wt% of polylactic acid, which is essentially not heat and flame resistant, the woven fabric according to the present invention,

- convective heat, expressed in 5.1 second t _HTI evaluating to B1,

Radiant heat expressed in t _{24 ° C., 20 kW / m 2,} evaluated at _{C 1} , and

Represents the heat of contact, expressed as a t _threshold of 7.2 seconds, evaluated as F1.

The evaluation is defined in DIN EN ISO 11612, meaning that the woven fabric meets the minimum requirements for heat and flame protective clothing.

Experiment 2

In Experiment 2, three woven fabrics (Example 1 and Comparative Examples 2 and 3 according to the invention) were tested and their properties compared. CE3 is a comparative example similar to Example 1. It contains similar amounts of para-aramid staple fibers and meta-aramid staple fibers but no polylactic acid staple fibers. The results are shown in Table 3.

TABLE 3

The following conclusions can be drawn from Table 3:

The wear resistance of Example 1 according to the present invention represents 120,000 cycles, which is 50-100% higher than the comparative woven fabric (CE2: 60,000; CE3: 80,000).

The peeling resistance of Example 1 according to the invention is at least one level higher than the peeling resistance of CE2 and CE3, and the difference between Example 1 and CE2 and CE3 becomes more apparent in a higher number of cycles. For 5,000 and 7,000 cycles, the difference is two levels.

Comparison of Example 1 with CE3 shows that Example 1 with polylactic acid staple fibers has better peeling resistance and wear resistance.

Claims (15)

A textile fabric comprising staple fiber yarns made of a staple fiber blend, wherein the blend comprises meta-aramid staple fibers, para-aramid staple fibers and polylactic acid staple fibers. The method of claim 1, wherein the blend is based on the weight of the blend,
30 to 90 wt% of the meta-aramid staple fiber,
5 to 60 wt% of the para-aramid staple fiber, and
Textile fabric comprising 5 to 40 wt% of the polylactic acid staple fibers. The method according to claim 1 or 2, wherein the unitary length of the meta-aramid staple fiber is 30 to 140 mm, the single length of the para-aramid staple fiber is 30 to 140 mm, and the polylactic acid staple fiber Textile fabric with a single length of 30 to 140 mm. The linear density of the said meta- aramid staple fiber is 0.8-7dtex, the linear density of the said para-aramid staple fiber is 0.8-7dtex, and the linear density of the said polylactic acid staple fiber is a Textile fabric, wherein 0.8 to 7 dtex. 5. The textile fabric as claimed in claim 1, wherein the blend further comprises 5 wt% or less of antistatic staple fibers based on the weight of the blend. 6. The textile fabric as claimed in claim 5, wherein the antistatic staple fibers are 30 to 140 mm in length and 0.8 to 7 dtex in linear density. The method according to any one of claims 1 to 6, wherein the meta-aramid staple fibers are poly (meth-phenylene isophthalamide) staple fibers, and the para-aramid staple fibers are poly- (p-phenylene terephthales). Amide) staple fibers or poly (p-phenylene-3,4'-oxydiphenylene terephthalamide) staple fibers, wherein the polylactic acid staple fibers are poly-L-lactic acid staple fibers or poly-D-lactic acid staple fibers or A textile fabric, which is a staple fiber made of a racemic mixture of poly-L-lactic acid and poly-D-lactic acid or a staple fiber made of a stereo composite of poly-L-lactic acid and poly-D-lactic acid. The textile fabric as claimed in claim 1, wherein the yarn is made from the blend by ring spinning or air jet spinning. The textile fabric according to claim 1, wherein the textile fabric is a woven or knitted textile fabric. The textile fabric of claim 9, wherein the textile fabric is a woven textile fabric having a twill or plain weave structure. The yarn of claim 10 wherein the twill or plain weave construction comprises one or more warp systems and one or more weft systems, wherein the one or more warp systems and the one or more weft systems have yarns having the same blend of staple fibers. Or yarn with different blends of staple fibers. The textile fabric as claimed in claim 1, wherein the grammage of the textile fabric is between 50 and 350 g / m 2. The blend of claim 1, wherein the blend is based on the weight of the blend, up to 95% aramid staple fibers, preferably up to 90% aramid staple fibers, more preferably A textile fabric comprising up to 80% aramid staple fibers or up to 70% aramid staple fibers. Garment comprising at least one textile fabric according to any one of claims 1 to 13. Use of the textile fabric according to any one of claims 1 to 13 for producing work clothes.