前苏联专利SU1715209A3 Method of obtaining heat-resistant fibers

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专利摘要:
Heat resistant organic fibers comprising a wholly aromatic polymer having amide group and/or imide group, said fibers having properties satisfying the following formulas and wherein Tm is a melting point; Tex is an exotherm starting temperature; Xc is a degree of crystallization; DE is an elongation; DSR is a dry shrinkage factor at Tm; and DSR(Tm + 55°C) is a dry shrinkage factor at Tm + 55°C. The process for producing the fibers is also disclosed.
公开号:SU1715209A3
申请号:SU874202688
申请日:1987-05-20
公开日:1992-02-23
发明作者:Асано Содзи；Охмори Акио；Акияма Акитсузу；Осава Масанори；Сизука Кохен；Коуно Масахиро
申请人:Курарей Ко Лтд (Фирма)；Мицуи Тоацу Кемикалз Инк (Фирма)；
IPC主号:

专利说明:

This invention relates to chemical fiber technology, in particular to the production of heat-resistant aromatic polyamide fibers.
The purpose of the invention is to obtain fibers with a low shrinkage ratio.
Lime 1: Getting aromatic polyamide.
Terephthalic acid (16b, 0t, 0.9991 mol), monopotassium terephthalate (2.038 g) and anhydrous M, H-dimethylsilylene urea (1600 ml) are loaded into a three-liter separation flask equipped with a stirrer, a thermometer, a condenser, and a nitrogen supply tube. in the atmosphere
nitrogen and heated with stirring to 200 ° C in an oil bath. Maintaining the contents of the flask at 200 ° C, a solution of toluene-2,4-diisocyanate (174.0 g, 0.9991 mol) in anhydrous M, M-dimethyl-urea (160 ml) is added dropwise through a dropping funnel over 4 hours. and continue the interaction for another 1 h. Then stop heating and the reaction mixture is cooled to room temperature. A portion of the reaction mixture is taken and poured into water, vigorously stirring to precipitate a white polymer. Then the polymer is washed with plenty of water and dried at about
150 ° C under reduced pressure for 3 h.
The logarithmic viscosity of the polymer forming (95% H2SO4. 0.1 g / dL, 30 ° C) is 2.2. The content of the polymer in the polymerization solution is 11.0 wt.%, The viscosity of the specified solution 420 P (Brookfield viscometer. 50 ° C). Then, the identity of the obtained polymer with poly (4-methyl-1,3phenylenetetraphthalamide) was confirmed by the data of IR and NMR spectra.
Fiber production from poly (4-methyl-1,3phenylene terephthalamide).
A spinning solution, from which air bubbles are removed, is obtained by filtering the solution described by polymerization at 50 ° C under reduced pressure. Then, maintaining the temperature at 50 ° C, the solution is spun out of the solution through a die with 600 round holes (hole diameter 0.11 mm) at a speed of 54.5 g / min with a feed into an aqueous coagulation bath containing 40% a solution of CaCl2 and 8% S, m-dimethylethylene urea at 80 ° C. After passing the strands with a spinnerette through a coagulation bath, these strands are subjected to wet stretching at a stretch ratio of about 1.6 times in a bath containing 40% CaCIa and 8% N, N-dimethyl ethylene urea. Next, the threads are thoroughly washed with water in a washing bath, which contains hot water at C, and after oiling the threads are passed through a hot air dryer with a temperature of 150 ° C to dry them, in order to obtain chemical fiber (strands) freshly heated by wet heating. .
This newly spun fiber has an ellipsoidal section, but uniform. The fiber has a weight titer of 2900 denier (600 filaments). The obtained sulfur-free raw fiber is subjected to stretching during drying with heating to 430 ° C with an stretching ratio of about 2.4 times in a drying-broaching machine under nitrogen to form poly (4-methyl-1,3-phenylene-terephthalamide) polymer fibers.
The resulting fibers have the following properties. Weight number of elementary fiber in denier 2; strength 5.8 g / denier; elongation of 25.4% Yang modulus 88 g / den; melting point Tm 425 ° C; the initial temperature of the exotherm is Te 330 ° C; Tm - Tech 95 ° C; the degree of crystallization XC 24%; shrinkage ratio when drying DSR Crm) DSR (425 ° C) 13%;
DSR (Tm + 55 ° C) DSR (480 ° C). one
DSR (Tm) DSR (425 ° C)
These values show excellent overall fiber properties along with excellent dimensional stability at temperatures below their melting point.
From the proposed fiber receive a knitted fabric and then subjected to
Flammability test. When the flame is removed, the fire immediately goes out, and this canvas reveals the ability to self-extinguish. In addition, the fibers in the charred part do not stick together strongly after burning.
In addition, the proposed fiber is tested for dyeability using a dispersed dye (5%) with a carrier at 140 ° C for 60 minutes.
Fibers of coloration (bt to the average degree and deeper tones relative to the tested 4 colors, namely, red, cyan, magenta, and yellow. The degree of dye pick-up is 60-85%.
Example 6: Preparation of poly (4-methyl1, 3-phenylene terephthalamide) t (4-methyl-1,3: phenyleneisophthalamide) n (m: n 9: 1).
Aromatic polyamide is prepared analogously to example 1, except that instead of terephthalic acid, 10 mol% of Levic acid isophthalic acid is taken. The logarithmic viscosity of the polymer obtained is 2.3. The polymer content of the polymerization solution is 11.9 May. %, solution viscosity 390 P
0 ° C). In addition, the identity of the polymer with poly (4-methyl-1,3-phenylene terephthalamide) t (4-methyl-1,3-phenylene isophthalamide) p (m: n 9: 1) is confirmed by IR and NMR spectra.
Preparation of poly (4-methyl-1,3-phenylene terephthalamide) t (4-methyl-1,3-phenylenisophthalamide) n (m: n 9: 1) fibers.
Aromatic polyamide fibers are prepared according to the procedure of Example 1, except that the spinning solution is replaced by the polymerization solution described.
The resulting fibers have the following properties. The weight number of the elementary thread is 2 denier; strength 5.3 g / deNye; elongation of 29.3%; Young's modulus of 81 g / den; Tm 410 ° C; Tech 315 ° C; Tm - Tech 95 ° C; Hc 20%; DSR (Tm): DSR (410 ° C) 10%.
DSR (Tm-55 ° C) DSR (465 ° C) g DSR / TshDSR (410PC)
The indicated values show excellent overall fiber properties along with
with excellent dimensional stability at temperatures above its melting point.
A knitted fabric is obtained from this fiber and then subjected to a flammability test. When the flame is removed, the fire immediately goes out, and this canvas reveals the ability to self-extinguish. In addition, the fibers in the charred part do not stick together strongly with one another after fire.
In this case, the fibers obtained have a dyeability that is identical to that obtained in example 1 according to a similar dyeability test.
Example 3. Obtaining poly (m-phenylenesophthalamide).
A two-liter separating flask equipped with a stirrer, a thermometer and a dropping raven. With a jacket for cooling is charged with isophthalic chloride: hey acid (250.2 g, 1.232 mol) and anhydrous tetrahydrofuran (600 ml) to obtain a solution. The solution is then cooled to 20 ° C by passing a cooling medium through the jacket. A solution of m-phenylenediamine (133.7 g, 1.237 mol) in anhydrous tetrahydrofuran (400 ml) was added dropwise through an addition funnel over 20 minutes with vigorous stirring. The resulting white emulsion is quickly poured into ice-cooled water, which contains anhydrous sodium carbonate (2.464 mol), while stirring vigorously. The temperature of the resulting suspension is quickly raised to about room temperature. Then, after adjusting the pH to 11 with sodium hydroxide, the suspension is filtered and the precipitate formed after filtration is thoroughly washed with plenty of water, dried overnight at 150 ° C to yield polymer, i.e. PMIA of the polymer The logarithmic viscosity of the polymer obtained is 1.4.
Production of poly (m-phenylene isophthalamide) fibers.
A spinning solution, which is freed from air bubbles, is obtained by dissolving the PMIA powder in M-methyl-2-pyrrolidone (NMP), which contains 2% LiCl of LiCl in the amount of 2% by weight of NMP to obtain a solution containing 22% by weight of NMP, and remove air from solution at 80 ° C, under reduced pressure. Then, keeping the temperature at 80 ° C, the spinning solution is drawn from a die with 100 round holes (hole size in diameter 0.08 mm) at a feed rate of 5.2 g / min to an aqueous coagulation bath (H1 containing 40% CaCl2 at a temperature of 80 ° C. Filamentary filaments drawn from a spinneret are passed through a bath of hot water at a temperature of 80 ° C by means of rollers.
B rotating at a speed of 10 m / min, for thorough washing with water. Then the filament yarns are subjected to wet stretching with heating at a stretching ratio of 2.88 and between the rollers in the hot
0 water. After oiling, the yarn is passed through a hot air dryer at 150 ° C to dry them to obtain freshly formed chemical fiber.
Specified freshly spun fiber
5 has a cocoon-like shape in section, but uniformly. The fiber has a weight titer of 358 denier / 600 filament yarns. Then, the freshly spun fiber is subjected to dry stretching with heating G1 and an stretching ratio of 1.88 times on a hot plate at 310 ° C to obtain poly (m-phenylene isophthalamide) fiber.
The fiber thus obtained has the following properties. Weight
5 number of an elementary thread 2 denier; strength 4.9 g / denier; elongation of 28.5%: Young's modulus of 80 g / den; TT 425 ° C; Tech 40.5 ° С: Тт Tech 20 ° С: Хс 25%; DSR (Tm): DSR (425 ° C) 16%.
DSR (Tm + 55 ° C)) j DSRCTm) DSR (425 ° C)
5PMIA fibers exhibit excellent overall fiber properties; dimensional stability at a temperature higher than the melting point and worse than that obtained in examples 1 and 2.
pI of the specified PMIA fibers receive
knitted fabric, which is subjected to a flammability test (flammable). When it is removed from the flame, the fire immediately ceases, and the fiber
It clearly shows the ability to extinguish. However, the fibers in the burned part strongly stick together with one another after burning and lose their fibrous form. In addition, a test was carried out on the ability of the PMIA fibers to be described to be described using the same procedure as described. In this case PMIA fibers are barely dyed in any dye, and the dyeing properties are lower than those obtained in the examples.
e 1 and 2. The degree of pick dye 20-23%.
PRI me R 4. Obtaining poly (4-methyl1, 3-phenylenisophthalamide).
The polymerization is carried out according to the method described in example 1.
A divided flask was loaded with isophthalic acid (166.1 g, 1.0000 mol), monosodium isophthalate (0.9405 g) and anhydrous M, N-dimethylethylene urea (1000 ml), and the mixture was heated to 200 ° C in an oil bath. While maintaining this temperature, a solution of toluene-2,4-diisocyanate (174.1 g, 1.000 mol) in anhydrous S, N-dimethylethylene urea (200 ml) is added dropwise through an addition funnel over a period of 4 hours and the reaction mixture is heated for another 1 h. Then the heating is stopped and the reaction mixture is cooled to room temperature. Thereafter, a portion of the reaction mixture is taken and the method of Example 1 is carried out. The logarithmic viscosity of the obtained polymer is 2.2. The polymer content of the polymerization solution is 20 wt.%, The viscosity of the solution is 230 P (Brookfield viscometer, 80 ° C).
Production of poly (4-methyl-1,3phenyleneisophthalamide) fibers.
A spinning solution, which is freed from air bubbles, is obtained by filtering said polymerization solution at 80 ° C under reduced pressure. Then, maintaining the temperature at 80 ° C, the pr - is carried out. from a solution with a draw through a die with 300 round holes (hole diameter 0.08 mm) at a rate of admission to a coagulation anhydrous bath containing 41% CaCl2 with a temperature of 80 ° C. Filament yarns formed from a spinneret through a coagulation the bath is passed through a hot water bath at 80 ° C using rollers at a speed of 10 m / min to thoroughly rinse with water, and then is drained by a wet method with heating at a stretch ratio of 2.34 times between the rollers in hot water at 98 ° C. After filler treatment with filler the yarns are passed through a hot air dryer at 150 ° C to dry them to obtain freshly formed fiber that has been drawn in the wet state.
Said freshly spun fiber has a cocoon shape in the section. The fiber has a weight titer of 1,310 denier / 300 el. fibers. Freshly dried fiber is subjected to dry stretching by heating with a stretching ratio of 2.18 times on a hot plate at 310 ° C, poly (4-methyl-1,3-phenylenisophthalamide) fiber is obtained.
The fiber thus obtained has the following properties. The weight number of the elementary fiber is 2 denier; strength 4 g / denier; 35% elongation: Young's modulus 81 g / den: Tm 390 ° C; Tech 290 C; Tgp - Tech 100 ° C; Hc 25%; DSR OHT): O5P (390 ° C) 83%.
Thus, although the general properties of the fiber are good, shrinkage when heated at a temperature above its melting point is significant and its dimensional stability is lower. To determine the value of the formula
DSR (Tm + 55 ° C) DSR (Tm)
measurement is necessary (Тt + 55 ° С) DSR (445 ° С). However, it cannot be measured, since any suitable specimen cannot be obtained due to significant fiber deformation.
According to the method described in example 1 and 2, a flammability test was performed, and the sample of the web showed self-extinguishing ability. However, the shrinkage of the knitted fabric is substantial, and the fibers in the burned part adhere firmly to one another after burning.
PRI me R 5. Preparation of poly (4-methyl-1, 3-phenylene terephthalamide) t (4-methyl-1,3 phenylenisophthalamide) p3 (nn: 70:30).
The polymer was prepared according to the same procedure of Example 1, using terephthalic acid (116.3 g, 0.700 mol), isophthalic acid (49.8 g, 0.3000 mol), monopotassium terephthalate (1.021), toluene-2,4-diisocyanate (174 , 1 g, 0.9997 mol), N, N -dimethylethylene urea (1,600 ml).
The logarithmic viscosity of the obtained polymer is 1.8, the polymer content of the polymerization solution is 20 wt.%, The viscosity of the solution is 340 N (Brookfield visco temperature, 80 ° C).
Fiber production from polyE (4-methyl1, 3-phenylene terephthalamide) n1 (4-methyl-1,3phenylisophthalate) n (m: n 70:30).
The fiber is prepared according to the procedure of Example 4, using the polymerization solution as the spin solution.
The fibers thus obtained have the following properties. The weight number of the elementary fiber is 2 denier; strength 4.8 g / denier; elongation of 31%; Yang module 83 g / den; Tm.395 ° C: Tech 298 ° C; Tg - Tech 77 ° C: Xc 16%: DSR (Tm): DSR (395 ° C) 20%.
DSR (T) DSR (45QPC) DSR (Tm) DSR (395 ° C)
Thus, the fiber has low melting and shrinkage during dry heating.
rises rapidly at temperatures above its melting point. Therefore, the shape of the fiber at high temperature is lower when compared with the agromatic polyamide fibers described in examples 1 and 2.
PRI me R b. Getting aromatic polyamide. A three-liter separating flask equipped with a stirrer, a thermometer, a refrigerator, a dropping funnel and a nitrogen supply tube is charged with pyromellitic acid dianhydride (PMDA, 120.01 g, 0.5503 mol), anhydrous M-methyl-2-pyrrolidone (2.200 ml) and heated with stirring to 180 ° C in an oil bath. Maintaining the reaction mixture at 180 ° C, a solution of biphenyl-3,3-dimethyl-4,4-diisocyanate (GODI, 146.13 g, 0.5530 mol) in anhydrous M is added dropwise over 30 minutes through an addition funnel. -methyl-2-pyrrolidone (200 ml), and the reaction is continued for another 30 minutes Then the heating is stopped and the reaction mixture is cooled to room temperature. A portion of the reaction mixture is taken and poured into water with vigorous stirring to precipitate a pale yellow polymer. The polymer is additionally washed with a large amount of water and dried at 150 ° C under reduced pressure for 3 hours.
Logarithmic viscosity:; studied polymer (95% H 2 SO / 1, 0.1 g / dL, 36 ° C) 1.20. The polymer concentration of the polymerization solution is 9.9 wt.%; The viscosity of the said solution is 300 P (Brookfield viscometer, 50 ° C).
Fiber production from poly (TODi) PMDA imido. The specified polymerization solution is condensed to a polymer concentration of 12 wt.% At 90 ° C under reduced pressure. This solution is deaerated at 90 ° C under reduced pressure to obtain a spin solution, from which air bubbles are removed ,; Then, maintaining the temperature at 90 ° G, from the solution, wet molding is carried out with a draw through a die with 600 round holes (hole diameter 0.09 mm) into a water coagulation bath containing 30% CaCl2 and 10% M-methyl- 2pyrrolidone, at 90 ° C. Gel-like filament yarns, formed through a die, are immersed in a solvent extraction bath containing 20% CaCla and 5% N-methyl-2-pyrrolidone at 90 ° C to bring the solvent content in the filaments to 50% .
The obtained fibers are passed into a bath (plasticization) for wet stretching during heating, containing 20%
CaCL2 and 5% M-methyl-2-pyrrolidone at 90 ° C to carry out wet stretching at a draw ratio of 1.4 times. Then the fibers are thoroughly washed with hot water at 90 ° C. After sizing, the filament yarns are dried with hot air at 180 ° C, fed to a dry-heated oven at 445 ° C, and pulled out with a dry heat drying machine 2.5 times to obtain poly (TODI / PMDA) -imide fibers.
The fiber thus obtained has the following properties. The weight number of the elementary fiber is 1.5 denier; strength 4.3 g / denier; elongation of 19.5%; Young's modulus 112 g / den; TT 430 ° C; Tech 395 ° C; Tm - Tech 35 ° C; Xc 13%; DSR (Tm): DSR (430 ° C) 13%;
DSR (Tgl + 55 ° C) DSP (485 ° C) 192 DSRlJn,) DSP (43 (fC)
These values show excellent overall fiber properties along with excellent dimensional stability at temperatures above its melting point.
Example. Getting aromatic polyamideimide,
In a three-liter flask equipped with a stirrer, a thermometer, a cooler, a dropping funnel and a nitrogen supply tube, diphenylmethane-4,4bis (trimethyl imidic acid) (DMTMA, 273.10 g, 0.5000 mol), monopotassium terephthalate (1.021 g) and anhydrous N-methyl-2-pyrrolidone (2.500 ml) under nitrogen atmosphere, and heated with stirring to 180 ° C in an oil bath. Maintaining the reaction mixture at 180 ° C. Toluene -2,4-diisocyanate (2.4-TOI, 87.07 g, 0.5000 mol) is added dropwise through a dropping funnel for 2 hours, and another 30 min Then the heating is stopped and the reaction mixture is cooled to room temperature. A portion of the reaction mixture is taken and poured into water with vigorous stirring to precipitate a pale yellow polymer. The polymer is further washed with a large amount of water and dried at 150 ° C under reduced pressure for 3 hours. The logarithmic viscosity of the obtained polymer (95% HaSO, 0.1 g / dl, 30 ° C) is 1.30. The polymer concentration of the polymerization solution is 11 wt.%, The viscosity of the solution is 550 P (Brookfield viscometer, 50 ° C),
Production of poly (OMTMA / 2,4-T01) amidimide fiber.
A spinning solution, which is freed from air bubbles, is obtained by filtering said polymerization solution at 50 ° C under reduced pressure. Then, keeping the temperature at 50 ° C, the spinning solution is passed through a die with 1000 round holes (hole diameter 0.08 mm) into an aqueous coagulation bath containing 35% CaCl2 and 5% M-methyl-2-pyrrolidone at 80 ° C Gel filamentous filaments formed through a spinneret are subjected to wet stretching when heated with stretch grade 1.5 times in a plasticizing wet draw bath containing 20% CaCl2 and 3% M-methyl-2-pyrrolidone at 80 ° C The filament is then immersed in a solvent extraction bath with the same composition as that of the plasticization bath for wet spinning. Then the filament yarns are immersed in a second solvent extraction bath containing 10% CaCl2 and 1% N-methyl-2-pyrrolidone at 80 ° C, and then in a third solvent extraction bath containing 5% CaCl 2 and 5% G 1-methyl-2 -pyrrolidone, at 80 ° C. Then the filament yarns are washed with hot water at 80 ° C and dried with hot air at 150 ° C. The obtained elementary fiber is fed into a drying oven with dry heating at 400 ° C, and then pulled out with dry heating in a drying-shirting machine at cozffi, extracting agent 2.3 times with the release of poly (O TMA / 2,4-POI) amidimidnogo fibers.
The fiber thus obtained has the following properties. The weight number of the elementary fiber is 2 denier; strength 4.0 g / den; elongation of 28%; Yang module 70 g / den; Tm 390 ° C; Tech 295 ° C;
Tm - Tech 95 ° C; Xc 11%; DSR (Tm): DSR (390 ° C 11%.
DSR (TV + 56 ° C) DSRC445 ° C) Q DSR (Tn,) DSR (390 ° C)
These values show excellent overall fiber properties along with excellent dimensional stability when
temperature above its melting point.
In tab. 1 and 2 show the results of the method.

权利要求:
Claims (1)
[1]
Claims The method of obtaining heat-resistant fibers by molding from a solution of an aromatic polymer into an aqueous coagulation bath, plasticizing a stretch in a water bath at elevated temperature, washing, drying and orientational stretching, characterized in
obtain low-fiber fibers
shrinkage, as an aromatic polymer
use a polymer from the group, including
poly (4-methyl-1,3-phenylene terephthalamide};
poly (4-methyl-1,3-phenylene terephthalamide) t - (4-methyl-1,3-phenylene isophthalamide) p,. where m; n 9; 1; polyamide based on pyromellitic acid dianhydride and diphenyl-3, 3-dimethyl-4,4-diisocyanate;
polyphenylamine based on diphenylmethane4, 4-bis-trimellitic imidoacid and toluene-2., 4-diazocyanate, plasticizing stretching of a fiber containing 25-150 wt.% solvent,
performed at 40-95 ° C with a stretching ratio of 1.4-1.6 in a bath containing 10-40% by weight of calcium chloride and 5-10% by weight of a polymer solvent with a total content of these components 16-48
wt.%, and orientational stretching is carried out at 400-445 ° C with a stretching ratio of 2.3-2.5.
Table 1
CaClg 0% and DMZM 8%, CaCl 2 20 CaCl4 10%
6lit2

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同族专利:

公开号 | 公开日

IN169609B|1991-11-23|

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JPS63120108A|1988-05-24|

US4758649A|1988-07-19|

FI872227A|1987-11-22|

JPH0418044B2|1992-03-26|

CA1295447C|1992-02-11|

AU7326387A|1987-11-26|

NO168780B|1991-12-23|

NO872117D0|1987-05-20|

DE3777877D1|1992-05-07|

EP0246634B1|1992-04-01|

EP0246634A2|1987-11-25|

FI872227A0|1987-05-21|

PH22633A|1988-10-28|

BR8702624A|1988-02-23|

AU591285B2|1989-11-30|

EP0246634A3|1989-05-10|

CN1010790B|1990-12-12|

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引用文献:

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

JP11797086|1986-05-21|

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