KR960011582B1 - A pack for spinning of aromatic polyamide fiber - Google Patents

Abstract

The apparatus for spinning totally aromatic polyamide fiber is composed of (A) a spinning pack(1) with porous plates(13,15) and a nozzle(14), (B) a body(16) around the outer peripheral side of the pack(1), (C) a nitrogen flow passage(30) established according to the peripheral side of the body(16) having input holes at both sides and a porous plate(24) at lower part, (D) a spinning tube(21) established at lower part to one body with the pack(1), the body(16) and the nitrogen flow passage(30). In this equipment, a cooling jacket(19), in which cooling oil flows, is established between the spinning pack(1) and the body(16); in the lower part of it, the input hole(22), which is outer side of the spinning tube(21) connects to the input tube(20); and in the upper part of it, a pcck housing(17) having a output tube(18) is established.

Description

Spinning pack device for wholly aromatic polyamide fiber

1 is a side cross-sectional view of the fiber spinning pack apparatus according to the present invention,

2 is a cross-sectional view taken along the line A-A of FIG.

* Explanation of symbols for main parts of the drawings

1: Pack 10: Top Lead

11: supply piping 12: filter

13, 15, 24: perforated plate 14: detention

16 body 17 pack housing

18: outlet pipe 19: cooling jacket

20: inlet tube 21: radiation tube

22: inlet 23: insulation

25: Bolt 26: Adapter

27: Gasket 28: Hool

29: ring 30: nitrogen inlet passage

The present invention relates to a spinning device for spinning of an aromatic polyamide fiber, and more particularly, in order to prevent overheating of the spinning solution of the wholly aromatic polyamide to improve physical properties and spinning operation properties for the final product The present invention relates to a spinning device for spinning of an aromatic polyamide fiber provided with a pack housing through which cooling oil flows on the periphery of the pack.

In general, in the case of manufacturing the wholly aromatic polyamide fibers, first the wholly aromatic polyamide spinning solution is prepared and then spun into a spinning barrel using a dry spinning pack, wherein nitrogen is installed at the periphery of the dry spinning pack. After flowing through the inlet, it is supplied to the inside of the spinneret through the porous plate bordering the spinneret to heat the spinning solution. The heating of the spinning solution is to improve the physical properties of the fibers finally obtained by evaporating off the solvent contained in the solution. However, conventional dry radiator packs described in, for example, U.S. Patent No. 4,123,208, have been introduced at the pack site before nitrogen, which enters through the nitrogen inlet, comes into contact with the spinning solution when the spinning solution is spun into the spinneret via the pack. The heat was transferred to the working solution in advance, and the spinning solution was overheated instantaneously, thereby deteriorating the physical properties and the operation of the fiber finally obtained. This situation usually occurs when the aromatic polyamide spinning solution has a temperature of about 130 degrees Celsius during dry spinning, but the temperature of nitrogen flowing into the spinning barrel is about 370 degrees Celsius, so the temperature difference between the spinning liquid and nitrogen is large. Heat is transferred to the spinning solution when spinning through the pack.

That is, the conventional pack device does not have a cooling device, when spinning the spinning solution, the pack and the detention is overheated, the solvent is evaporated inside the pack, the final cut frequency of the fiber is very high, and also the polymer Pyrolysis is high and will corrode the device. In addition, since nitrogen gas is supplied from the side of the pack, the temperature distribution between the pack and the detention is generated. For example, the temperature of the pack and the detention is higher than the internal temperature, resulting in different physical properties of the fiber.

Therefore, the present inventors have earnestly researched to solve the problems as described above, and finally, when the dry spinning is performed by installing a cooling device between the pack for spinning the spinning solution and the inlet through which nitrogen is introduced, it is finally obtained. It has been found that the physical properties of the fiber as well as the spinning operation is improved, which leads to the present invention.

That is, an object of the present invention is to provide a wholly aromatic polyamide fiber spinning pack device by providing a cooling device to the spinning pack in order to improve the physical properties and spinning operation of the fiber.

Hereinafter, the present invention will be described in detail.

The present invention is a perforated plate and the spinneret is installed in the spinneret and the body is wrapped around the outside of the pack and the inlet is formed on both sides and the nitrogen flow passage is installed along the outer peripheral surface of the body with a perforated plate at the bottom And a spinning pack device of a wholly aromatic polyamide fiber composed of a spinneret installed integrally with a lower part of the pack, the body and the nitrogen flow passage. The inside is formed with a cooling jacket through which the cooling oil can flow, and a lower part thereof is connected to an inlet tube having an inlet formed on the outside of the radiator, and an upper part of the pack housing having an outlet tube formed therein. It is a spin pack device for aromatic polyamide fibers.

Referring to the present invention in more detail based on the accompanying drawings as follows.

The present invention is a device for installing a pack housing for cooling the hot nitrogen supplied to the periphery of the pack to spin the spinning solution in the spinning pack device used when manufacturing the wholly aromatic polyamide fibers, 1 shows a pack apparatus according to the present invention. In this figure, reference numeral 10 denotes a top lead, and at the center thereof is a Y-shaped supply pipe 11 for supplying a spinning solution, and a filter 12 and a porous plate 13 are fitted at both lower ends thereof. And the lower portion of the upper lead 10 is a porous plate 15, the detent 14 is installed is in the vertical direction with the body 16. Therefore, the spinning solution for producing the aromatic polyamide fiber coming through the supply pipe 11 of the upper lead 10 passes through the filter 12 and the porous plate 13 at the lower end thereof to disperse the pressure of the spinning solution. It is radiated through the detention 14 of the installed porous plate 15. Here, the spinning solution is prepared by copolymerizing a monomer consisting of isophthaloyl chloride and terephthaloyl chloride to metaphenylenediamine in an amide solvent.

On the other hand, the pack apparatus according to the present invention is the peripheral portion of the pack (1), that is, the pack (1) consisting of the upper lead 10 and the porous plate 15 which extends in the vertical direction with the body 16 as described above The pack housing 17 is installed between the bodies 16 to surround the pack 1, and the pack housing 17 has an outlet pipe 18 through which cooling oil is discharged at an upper end thereof. A cooling jacket 19 is formed in the central portion to allow the cooling oil to flow while surrounding the pack 1, and an inlet pipe 20 through which the cooling oil flows is connected to the lower end thereof. Here, the inlet pipe 20 is connected to the inlet port 22 is installed on the outside of the spinning tube 21 to the spinning solution is radiated and the outer surface of the inlet pipe 20 is a heat insulating material 23, for example, asbestos, etc. Surrounded by.

Therefore, the cooling oil enters into the cooling jacket 19 of the pack housing 17 through the inlet 22 and the inlet pipe 20 from the outside of the radiator 21 and surrounds the pack 1 of the cooling jacket 19. It rotates inside and then flows out through the outlet pipe 18. Here, it is preferable to form at least six inlet tubes 20 and outlet tubes 18 with respect to the radius of the pack device as shown in FIG.

On the other hand, the nitrogen to heat the spinning solution is applied through the nitrogen inlet passage 30 in the side portion of the pack (1) and then in contact with the body 16, the porous plate 24 at the bottom of the inlet passage (30) Through the inside of the spinning barrel 21 to enter the spinning solution to be radiated through the detention 14 and the inside of the spinning barrel 21 is to evaporate the solvent contained in the spinning solution.

Here, reference numeral 25 denotes bolts for missing parts in the pack device, 26 denotes an adapter for connecting the pack housing 17 and the outlet pipe 18, and 27 denotes preventing leakage of nitrogen gas or spinning solution. A gasket, 28 is a hole into which the bolt is to be inserted, and 29 is a ring.

Pack device according to the present invention as described above is supplied to the spinning solution of about 130 degrees Celsius through the supply pipe 11 of the top lead 10 spinning solution is the filter 12 at the bottom of the top lead 10 And through the porous plate 13 is radiated into the detention 14 is to enter the inside of the radiation cylinder (21).

At this time, in order to remove the solvent contained therein by heating the spinning solution inside the spinning barrel 21, nitrogen is supplied to the nitrogen inlet passage 30 and sent to the inside of the spinning barrel 21 through the porous plate 24. When the cooling oil is supplied through the inlet port 22 and the inlet pipe 20 to circulate inside the cooling jacket 19, the heat of nitrogen supplied through the nitrogen inlet passage 30 is discharged through the pack 1. Delivery to the use liquid is prevented and the circulating cooling oil is discharged through the outlet pipe 18.

Therefore, the pack apparatus according to the present invention is bounded by the pack portion and the nitrogen inflow passage through which the spinning solution passes in order to prevent preheating of the spinning solution by nitrogen to evaporate and remove the solvent contained in the spinning solution inside the pack. Since the cooling jacket is installed between the bodies that are thereby, the resulting physical properties of the fiber as well as the spinning operation is excellent.

Such a present invention will be described in more detail based on examples as follows.

Example 1

Isophthaloyl chloride and terephthaloyl chloride were copolymerized with methaphenylenediamine in a monomer composed of 95% by weight: 5% by weight, and a spinning solution was prepared so that it was 20% by weight with respect to N-methylpyrrolidone.

The spinning solution (temperature 130 ℃) was spun into a spinning tube through a porous plate of 2600 spinnerets and 0.15 mm in diameter, and 410 kg / hr of silicone oil having a temperature of 70 ℃ in the pack housing. Feed at a rate of. Subsequently, nitrogen having a temperature of 370 ° C. is supplied into the spinning barrel through a nitrogen inflow path to recover the solvent contained in the spinning solution by evaporation. The nitrogen cooled to 230 ° C. is heated and reused by increasing the pressure with a blower. It was. The spun filament was stretched after the temperature was lowered by the cooling water sprayed at the speed of 3500 kgk / hr at the bottom of the spinneret. At this time, the temperature of the stretching bath is 90 ℃, the stretching ratio is 3.5, the temperature of the washing bath is 50 ℃, the drying roll temperature is 130 ℃, the heat treatment temperature is 260 ℃ to prepare a filament as the final product.

The denier of the filament thus obtained was 4 denier, and the discharge amount was 364 kg / hr as calculated from the following equation.

Qms is the mass flow rate of the spinning solution discharged from the detention [kg / hr]

De is the denier of the final yarn [4 × 2600 = 10400 denier]

S is the draw ratio [3.5]

V ₁ is the linear velocity of the first roll [300m / min]

W ₂ is the weight fraction of polyamide in the spinning solution

The flow rate (Qmg) of nitrogen supplied in this example was 4,285 kg / hr as measured by a flow meter, the strength of the filament obtained above was 4.5 g / d, the elongation was 37%, and the operability was good. The operability here was good that cutting frequency was 3 times / day or less, and 4-10 / day was normal and 11 times / day was bad.

[Examples 2 to 4]

In this embodiment, as shown in Table 1, except that the polymer concentration, the discharge amount, the flow rate of nitrogen and the temperature of the silicon oil in the spinning solution was carried out as in Example 1, the results are shown in Table 2.

[Comparative Examples 1 and 2]

Except not using silicone oil, the same procedure as in Example 1 was carried out, but the polymer concentration, discharge amount, and nitrogen flow rate of the spinning solution were changed as shown in Table 3 below, and the results are shown in Table 4 below.

[Comparative Examples 3 and 4]

In Example 1, except that the temperature of the silicon oil is changed to 50 ℃ and 120 ℃, the same results as in Example 1 are shown in Table 5.

Claims (1)

A spinning pack (1) with perforated plates (13, 15) and detention (14) and a body (16) that surrounds the pack (1) in a cylindrical shape, with inlets on both sides, Nitrogen flow passage (30) installed along the outer circumferential surface of the body (16) with the plate (24) and the radiation cylinder (21) integrally installed below the pack (1), the body (16) and the nitrogen flow passage (30) In the spinning pack device of a wholly aromatic polyamide fiber consisting of), the cooling pack is installed so that the cooling oil flows while being installed while being wrapped while wrapping between the spinning pack (1) and the body (16) The jacket 19 is formed, the lower end is connected to the inlet pipe 20 is formed in the inlet port 22 is formed in the outer side of the barrel 21 and the pack housing in which the outlet pipe 18 is formed at the upper end ( 17) is provided for the spinning pack device of the wholly aromatic polyamide fibers.

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