CN111441117A - High-strength carbonized flame-retardant yarn - Google Patents

Abstract

A high-strength carbonized flame-retardant yarn belongs to the technical field of spinning. Uniformly mixing the flame-retardant viscose glue and the aramid fiber 1414; (2) clearing; (3) carding cotton; (4) drawing; (5) roving; (6) spinning; (7) spooling; the flame-retardant viscose, the para-aramid 1414 and the high-strength nylon filament are blended, the production and the processing are carried out according to the blending proportion (mass percentage) of 60 +/-3% of the flame-retardant viscose, 30 +/-3% of the 1414 para-aramid and 10 +/-3% of the high-strength nylon 30-40D filament, and 14 yarns are produced by adopting a core-spun yarn production mode. The flame-retardant fabric produced by the yarn has good flame retardance, no molten drop during carbonization, excellent comfort, high dyeing performance and high strength.

Description

High-strength carbonized flame-retardant yarn

Technical Field

The invention relates to the technical field of spinning, and discloses a high-strength carbonized flame-retardant yarn.

Background

With the improvement of protection consciousness of people, particularly the requirement of individual protection in special industries, a great deal of requirements appear on flame-retardant protective functional clothes, the problems of low strength, itchy wearing, secondary scald caused by melt dripping after combustion, single dyeing and the like appear in the use process of the conventional flame-retardant yarn for producing the protective clothes, and the reasonable matching of fibers with different performances is necessary to be researched and used, the key performances of various fibers are fully utilized, the yarn for producing the protective clothes which has comfortable wearability, high strength, flame retardance and no melt dripping during carbonization is developed, and the requirement of producing the special flame-retardant protective clothes is realized.

Disclosure of Invention

The invention aims to overcome the defect that the existing yarn for producing the flame-retardant protective clothing can not meet various performance requirements of the existing finished clothing, and provides the yarn for the flame-retardant protective clothing, which has good flame retardance, no molten drop during carbonization, excellent comfort, high strength and high dyeing performance, wherein the yarn is produced and processed by blending three fibers, namely flame-retardant viscose, para-aramid 1414, high-strength nylon filament and the like according to the blending proportion of 60 +/-3 percent of the flame-retardant viscose, 30 +/-3 percent of the para-aramid and 10 +/-3 percent of the high-strength nylon filament of 30-40D, and 14 yarns are produced by adopting a core-spun yarn production mode, so that various performance indexes of the blended yarn are improved, and the production requirement of the special flame-retardant protective clothing fabric is met.

The production process flow of the high-strength carbonized flame-retardant yarn comprises the following steps: (1) uniformly mixing the flame-retardant viscose glue and the aramid fiber 1414; (2) clearing; (3) carding cotton; (4) drawing; (5) roving; (6) spinning; (7) and (6) spooling.

Three fibers of flame-retardant viscose, para-aramid 1414 and high-strength nylon filament are blended, so that the high moisture regain performance of the flame-retardant viscose is fully utilized to improve the wearing comfort; the para-aramid 1414 is adopted, the high strength and high flame retardant property of the para-aramid 1414 are utilized, the flame retardant protection function and the applicability of the fabric are guaranteed, the high-strength nylon filaments are adopted as the framework, the yarn strength is improved, and the functional requirements of the special flame retardant protection fabric are met. And a core-spun spinning mode is adopted, so that the yarn strength is further improved. Meanwhile, the yarn count is designed to be 14, and the produced fabric has high air permeability and tear resistance.

The flame-retardant fabric produced by the yarn has good flame retardance, no molten drop during carbonization, excellent comfort, high dyeing property and high strength, and is suitable for various special operation places, in particular to operation places needing good camouflage property.

Detailed Description

The present invention will be further illustrated with reference to the following examples, but the present invention is not limited to the following examples.

The high-strength carbonized flame-retardant yarn has a blending ratio of 60 +/-3% of flame-retardant viscose, 30 +/-3% of 1414 para-aramid and 10 +/-3% of high-strength nylon filament, and the yarn count is 14.

Example 1

Domestic flame-retardant viscose: it is safe and non-toxic, produces no toxic gas during combustion, produces less smoke, has high flame retardance and lasting flame retardant effect, and can maintain the original form after carbonization or at the high temperature of 1100 ℃ to play a role in blocking. The paint does not melt or drip, reduces secondary damage such as scald and the like, and can be degraded after the use life cycle is finished; the dyeing is bright and the color fastness is high.

The main performance indexes of the flame-retardant viscose fiber are as follows:

linear density of fiber	2.2dtex	Length of fiber	51mm
				Dry breaking strength	≥2.0CN/dtex	Limiting oxygen index (L OI)	≥35％
Color fastness	Grade not less than 4	Alkali washability resistance	≤2％
				Duration of combustion	Less than or equal to 2 seconds	Smoldering time	Less than or equal to 2 seconds
Density of smoke	Dm4.0≤5	Composition of flue gas	Is non-toxic
				Melt dripping	Is free of	Safe ecological index	Class A (OEKO)

Para-aramid 1414:

the para-aramid 1414 fiber is adopted, and has the characteristics of high strength, high temperature resistance, tearing resistance, flame retardance and the like. The para-aramid fiber 1414 can be continuously used at a high temperature of 220 ℃, the thermal decomposition temperature is more than or equal to 530 ℃, and the domestic para-aramid fiber 1414 has excellent performances in the aspects of sun resistance and water washing resistance.

The main physical indexes of the para-aramid 1414 fibers are as follows:

linear density of fiber	2.2dtex	Length of fiber	51mm
				Breaking strength of single fiber	≥14.5CN/dtex	Limiting oxygen index (L OI)	≥28％
Melt dripping	Is free of	Color fastness to washing	4-5 stages
				Glass transition temperature	300℃	Color fastness to light	4-5 stages
Initial modulus	85GPA

High-strength nylon filament:

the high-strength nylon filament has high strength and excellent wear resistance. The main physical indexes of the high-strength nylon fiber are as follows:

linear density of fiber	44dtex	Limiting oxygen index (L OI)	≥25％
				Breaking strength of single fiber	≥8.0CN/dtex	Elongation at break	≥20％

The preparation of the high-strength nylon filament comprises the following steps:

1) drying and tackifying: conveying the nylon slices with initial relative viscosity of 2.5-3.0 into a drying tower, and performing countercurrent circulating drying by adopting nitrogen to obtain nylon ultrahigh-viscosity slices with water content of less than or equal to 200ppm and relative viscosity of 3.5-3.8;

2) melt extrusion: conveying the high-viscosity nylon chips into a screw extruder, wherein the temperature of each area of the screw is 285-310 ℃, and melting and extruding the high-viscosity nylon chips;

3) high-pressure spinning: enabling the melt extruded in the step 2) to enter a spinning box through a melt pipeline with the temperature of 280-295 ℃, quantitatively pressing the melt into a spinning assembly through a metering pump, and spraying the melt from a spinneret plate to form tows; the speed of the filament bundle is 5-10 m/min;

4) and (3) cooling and forming: the melt trickle sprayed after spinning is slowly cooled and then is cooled by side blowing to form a nascent fiber tow;

5) oiling and bundling: oiling the cooled filament bundles by using an oil tanker, wherein the oiling mode is emulsion oiling, and the oiling rate is controlled to be 1.0-1.3%;

6) stretching and shaping: carrying out stretching and shaping treatment on the bunched and oiled tows; the method comprises the following steps of stretching, wherein a group of feeding rollers is adopted for natural stretching, four pairs of hot rollers are adopted for two-stage hot stretching and one-stage relaxation heat setting, the total stretching multiple is 2.5-3.5, the orientation degree of the tows in the early stage is improved by improving the natural stretching ratio, and then two-stage hot stretching is adopted for continuously orienting the macromolecules of the tows, so that higher strength is obtained;

further preferably: the feeding roller is not heated, the natural draw ratio is more than or equal to 200, and the feeding roller is mainly used for pre-orienting the tows sprayed by the spinneret plate in a viscous state, so that the subsequent draw ratio is reduced, and the generation of subsequent drawn broken filaments is reduced; the speed difference between the feeding roller and the first group of hot rollers plays a role in tensioning the slivers, and the speed ratio is 1.02-1.06; the first group of hot rollers are 40-70 ℃, the second group of hot rollers are 150-190 ℃, the first-step stretching is carried out between the second group of hot rollers and the first group of hot rollers, the speed ratio is 1.6-2.5, the first group of hot rollers and the second group of hot rollers mainly function in heating the tows to the vitrification temperature, so that macromolecules have motion conditions, and molecular chains are arranged along the stretching direction; the third group of hot rollers is 200-250 ℃, the second-step stretching is carried out between the third group of hot rollers and the second group of hot rollers, the speed ratio is 1.2-1.8 times, the second-step stretching mainly has the effect of making up the deficiency of the first-step stretching, so that hydrogen bonds among macromolecules are weakened or disappear, the macromolecules are further oriented, and the strand silk reaches the highest strength; the temperature of the fourth group of hot rollers is 170-200 ℃, the tows are subjected to relaxation heat setting between the fourth group of hot rollers and the third group of hot rollers, the speed ratio is 0.95-0.98, and the fourth group of hot rollers are used for performing relaxation setting on the tows, so that the crystallinity of the tows is improved, and the precursor with a more stable molecular structure is obtained.

7) Winding: and (3) fully automatically winding the tows subjected to the stretching and setting treatment, setting the winding speed to 5200-5800 m/min, and winding to obtain the fine denier high-strength nylon fiber.

The preparation process of the high-strength carbonized flame-retardant yarn comprises the following steps:

1. the control key points of the fiber mixing in the production process are as follows:

the spun yarn is composed of three components of fibers, wherein aramid fibers are high in rigidity and poor in cohesive property with viscose in the production process, and are not beneficial to normal production, so that pretreatment of an oiling agent and an antistatic agent is performed before the spun yarn is used for 24 hours, a mixed reagent is prepared by adopting 2% of an oiling agent and 4% of the antistatic agent and water, the mixed reagent accounts for 10% of the total weight of the fibers, is uniformly sprayed on the surfaces of the fibers, and is used for 24 hours in advance.

Mixing the flame-retardant viscose and the pretreated aramid fiber in a cotton tank according to the proportion of 60/30, wherein the mixing uniformity determines the yarn quality and the comprehensive performance of the final garment material, and all fibers must be fully mixed to ensure the yarn uniformity and consistency; the blowing and carding process adopts a low-speed and light-weight process route to fully mix the single-fiber fibers.

2. Opening and picking process

Because the fibers have no impurities, the opening is important, the distance between the beater and the dust rod is shortened, the beater speed is reduced, and the distance between the dust rods is closed.

The opening and picking process adopts coiling equipment, an A002D type bale plucker, and the main process parameters are as follows: the beater speed is 900r/min, and the operating efficiency of the bale plucker is 95 percent. A036C type beater adopts a card wire beater, the gauge is 10cm, the beater rotating speed is 360r/min, the cotton feeding roller rotating speed is determined to be 70r/min according to the operating efficiency so as to ensure more and less beating, and the beater speed of A076C is 750 r/min. The ration of the cotton roll is 350g/m, the length of the cotton roll is 30m, and the elongation of the cotton roll is 1.0%.

3. Carding process

The process adopts A186F type low-speed carding machine, and the arrangement of card clothing is characterized in that cylinder card clothing adopts model 1830 × 1650D with low tooth root and tooth density, doffer adopts model 4030 × 1890 with high transfer performance, and cover plate adopts model JP520 with high tooth density.

The technological configuration adopts large-spacing, low-speed and light-weight. The main process configuration is as follows: the cylinder-cover plate gauge is 14mm, 12mm and 14 mm. The cylinder speed is 300r/min, and the licker-in speed is 550 r/min.

4. Drawing process

The drawing adopts FA306 type, the roller gauge and the draft distribution are controlled in emphasis, the first pass adopts 6 pieces of combination, the total draft multiple is 5.8 times, the back zone draft is 1.8 times, the draft ratio is 3.22, the roller gauge is 28 × 40mm, the roller speed is 238m/min, the last pass adopts 8 pieces of combination, the total draft multiple is 8.82 times, the back zone draft is 1.25 times, the draft ratio is 7.1, the roller gauge is 23 × 40mm, the roller speed is 220m/min, the head and tail combined pressure is adjusted to be maximum, the relative humidity of the drawing process is controlled at 68 percent, the drawing leather roller uses A, B component coating to be used after 2 times of treatment.

5. Roving process

The method is characterized in that an FA426 type roving frame is adopted for roving, a two-large two-small process is adopted for the roving process, namely, a process principle of large pressure, large gauge, low speed and small ration is adopted, so that the evenness of the roving is facilitated, the elongation is well controlled in the process of the roving, the elongation is required to be controlled within the range of 1.5 +/-0.5%, the difference of the front and back rows and the large and small yarns is within the range of 0.5%, and the main process parameters of the roving are cradle pressure 240 × 220 × 200N, roller gauge 35 × 50mm, jaw gauge 8.0mm, roving coefficient 82 and spindle speed 750 r/min.

6. Spinning process

The spinning method comprises the following steps of adopting an FA506 spinning machine, using a modified covering yarn device, wrapping a high-strength nylon filament with a mixed roving of flame-retardant viscose and aramid, controlling the key point of a spinning process to achieve the wrapping effect of staple fibers and the filament, uniformly covering the staple fibers on the outer surface of the filament, twisting and forming, configuring the specific process to be 14500rpm at spindle speed, 1.21 times of drafting multiple in a rear area, 30 × 48 of roller spacing, 5.5mm of jaw spacing and 390 of twist coefficient, adopting 68-degree medium-hardness rubber rollers and water drop type pressure bars in equipment, selecting a titanium alloy steel collar PG14254 steel collar with strong self-lubricating function in a rolling and twisting part, and selecting a high-bow chromium-plated steel wire loop as the steel wire loop.

7. Winding process machine

The automatic winder adopts an automatic winder of German Schleffer company AC338RM, and the winding process is mainly selected from an electric cleaning process, wherein the winding speed is 1000m/min for N350%, S160% × 2.0.0 cm, L35% × 50cm, T35% × 80 cm..

The main properties of the finished yarn are shown in Table 1.

Variety of (IV) C	Flame-retardant viscose/aramid 1414/high-strength chinlon 14S
		Coefficient of variation by weight of hectometer CV%	2.0
Actual dry weight (g/100)Rice)	3.900
		Weight deviation of one hundred meters (%)	1.0
Actual figure (special)	42.0
		Moisture regain (%)	7.8
Single yarn breaking strength (cN/tex)	22.8
		Correction strength (cN)	963.5
Single strong coefficient of variation CV%	7.4
		Yarn cv	9.45
Details of	0
		Nub	8
Cotton knots	12
		Lowest strength	854.3
Twist factor	387

Table 1: main properties of finished yarn

A high-strength carbonized flame-retardant yarn is used for weaving 14-count high-wearability flame-retardant gray fabric with 60% of flame-retardant viscose, 30% of 1414 para-aramid and 10% of nylon filament. The gray fabric has the advantages that the combustion performance of the gray fabric reaches the standard flame-retardant A level of GB 17591-2006 flame-retardant woven fabric, the gray fabric is completely carbonized without melting or dripping during combustion, and the physical index exceeds the excellent level of GB/T406-2008, so that the gray fabric can be used by special operation tools for fire fighting, military and the like with strong force.

Claims (5)

1. The preparation method of the high-strength carbonized flame-retardant yarn is characterized by comprising the following steps of:

(1) uniformly mixing the flame-retardant viscose glue and the aramid fiber 1414; (2) clearing; (3) carding cotton; (4) drawing; (5) roving; (6) spinning; (7) spooling; the flame-retardant viscose, the para-aramid 1414 and the high-strength nylon filament are blended, the production and the processing are carried out according to the blending proportion (mass percentage) of 60 +/-3% of the flame-retardant viscose, 30 +/-3% of the 1414 para-aramid and 10 +/-3% of the high-strength nylon 30-40D filament, and 14 yarns are produced by adopting a core-spun yarn production mode.

2. The preparation method of the high-strength carbonized flame-retardant yarn according to claim 1, wherein the main performance indexes of the flame-retardant viscose fiber are as follows:

linear density of fiber 2.2dtex Length of fiber 51mm Dry breaking strength ≥2.0CN/dtex Limiting oxygen index (L OI) ≥35％ Color fastness Grade not less than 4 Alkali washability resistance ≤2％ Duration of combustion Less than or equal to 2 seconds Smoldering time Less than or equal to 2 seconds Density of smoke Dm4.0≤5 Composition of flue gas Is non-toxic Melt dripping Is free of Safe ecological index Class A (OEKO)

The main physical indexes of the para-aramid 1414 fibers are as follows:

linear density of fiber 2.2dtex Length of fiber 51mm Breaking strength of single fiber ≥14.5CN/dtex Limiting oxygen index (L OI) ≥28％ Melt dripping Is free of Color fastness to washing 4-5 stages Glass transition temperature 300℃ Color fastness to light 4-5 stages Initial modulus 85GPA

High-strength nylon filament:

the high-strength nylon filament has high strength and excellent wear resistance. The main physical indexes of the high-strength nylon fiber are as follows:

linear density of fiber 44dtex Limiting oxygen index (L OI) ≥25％ Breaking strength of single fiber ≥8.0CN/dtex Elongation at break ≥20％

。

3. The preparation method of the high-strength carbonized flame-retardant yarn according to claim 1, wherein the aramid fiber is pretreated with an oiling agent and an antistatic agent before being used for 24 hours, a mixed reagent is prepared by adopting 2% of an oiling agent and 4% of an antistatic agent and water, the mixed reagent accounts for 10% of the total weight of the fiber, is uniformly sprayed on the surface of the fiber, and is used for 24 hours in advance.

4. The preparation method of the high-strength carbonized flame-retardant yarn according to claim 1, which is characterized by comprising the following steps: (1) mixing the flame-retardant viscose and the pretreated aramid in a cotton tank to fully mix the fibers; preferably, the blowing and carding process adopts a low-speed and light-weight process route to fully mix single-fiber fibers;

(2) opening the scutching process, shortening the gap between the beater and the dust rod, reducing the beater speed, and closing the gap between the dust rods; so that the ration of the cotton roll is 350g/m, the length of the cotton roll is 30m, and the elongation of the cotton roll is 1.0 percent;

(3) and cotton carding process;

(4) drawing process

Drawing adopts FA306 type, and the key points are to control roller gauge and draft distribution.6 pieces of drawing are adopted in the first pass, the total draft multiple is 5.8 times, the back zone draft is 1.8 times, the draft ratio is 3.22, the roller gauge is 28 × 40mm, the roller speed is 238m/min, 8 pieces of drawing are used in the last pass, the total draft multiple is 8.82 times, the back zone draft is 1.25 times, the draft ratio is 7.1, the roller gauge is 23 × 40mm, the roller speed is 220m/min, the head and tail combined pressure is adjusted to the maximum, the relative humidity of drawing process is controlled at 68%, and the drawing leather roller is used after 2 times of treatment by A, B component coatings;

(5) roving step

The roving process is suitable for adopting a 'two-large two-small' process, namely, a process principle of 'large pressure, large gauge, low speed and small ration' so as to be beneficial to uniform roving evenness; the roving process is characterized in that the elongation is well controlled, the elongation is required to be controlled within the range of 1.5 +/-0.5%, and the difference between front and rear rows and the size of yarns is within the range of 0.5%;

(6) spinning step

Wrapping the high-strength nylon filament yarn with a mixed roving of flame-retardant viscose and aramid; the key point of the spinning process is that the short fibers are uniformly covered on the surface of the filament and are twisted to form;

(7) and a winding machine.

5. A high tenacity carbonized flame retardant yarn prepared according to the method of any one of claims 1 to 4.