KR20080099649A - Method of folding synthetic filament - Google Patents

Abstract

A coarser denier method of the wholly aromatic polyamide filament using the electrical type tension regulating device is provided to manage the withdrawal tension regularly by setting up the electrical type withdrawal tension regulating device in each krill in which the bobbin sticks which filament is rolled. A coarser denier method of the wholly aromatic polyamide filament using the electrical type tension regulating device comprises as follows. The bobbin(2) uses a plurality of driver rollers(3a,3b,3c) and filament is rolled. The creel unit is made of a plurality of krills(1) rotating with the withdrawal tension of filament based on the axis of rotation. After combining filaments from the creel unit with withdrawal, it reels these in the winder(5) and filament is the coarser denier. The electrical type withdrawal tension regulating device(6) is set up in krill and the speed of rotation of krill is controlled so that the withdrawal tension of filament be regularly preserved.

Description

Method of folding the filament {Method of folding synthetic filament}

1 is a schematic diagram of the present invention.

Figure 2 is a schematic diagram of the electric maritime tension control mechanism installed in the creel of Figure 1;

* Explanation of symbols on the main parts of the drawings

1: Creel 2: Bobbin of synthetic fiber

3a, 3b, 3c: Driver Roller 4a, 4b: Guide Roller

5: winder 6: electric maritime tension control mechanism

6a: Maritime tension sensor 6b: controller

6c: Brake 6d: Sprocket

The present invention relates to a method for converting filaments, such as wholly aromatic polyamide filaments, and more specifically, filaments that can be spliced and wound in a lead-free state after dissolving a plurality of strands of filaments with the same sea tension. It relates to the method of Taesomdo.

In the manufacture of optical cables, wholly aromatic polyamide filaments, which are a kind of filaments, are used as reinforcing materials for covering an optical fiber in a state in which multiple strands are spun together (hereinafter referred to as "filament flocking bundle").

In order to increase the surface area and improve the modulus when covering the optical fiber, it is desirable that the filament filament bundle be kept free of twist.

Typically, when the filament yarn bundle is provided with a twist, the modulus is lowered and the surface area is narrowed when covering the optical fiber.

When there is no twist in the filament yarn bundle as described above, when dissolving the filament yarn bundle for a post process such as covering the optical fiber, a part of the filament constituting the filament yarn bundle is drooped due to the tension deviation, thereby causing a partial droop. The problem occurs frequently.

Therefore, it is very important to give uniform filament tension to each filament in the process of filament filament bundle bundle by flocking multiple filaments.

In the conventional method of the filament of the filament, a bobbin (2) in which the filament is wound is inserted using a plurality of driver rollers (3a, 3b, 3c), and a plurality of krills (1) rotated about the rotation axis by the filament's sea power. After dissolving and filamenting the filaments from the krill portion consisting of) and wound them in the winder (5) to make the filament, but the conventional method is provided with a means for effectively controlling the sea tension of each filament to be dismissed from the bobbin There was a problem that the sea tension of the filament to be dissolved in each krill can not be constantly adjusted.

As a result, the filament-plyed bundles manufactured by the conventional method of filamentation of the filament were squeezed down due to a part of the filament due to the tension deviation during dismantling in the post process.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method for converting a filament to be filamented and wound in a lead-free state by dissolving a plurality of strands of filaments with a uniform sea tension by solving these problems.

The present invention is to provide a method for the Taeseodo filament that can manage the sea-power constant by installing an electric sea tension tension mechanism to each of the krill (1) to which the filament is wound bobbin to achieve the above object .

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail.

As shown in Figs. 1 and 2, the filament-forming method of the filament according to the present invention uses a plurality of driver rollers 3a, 3b, and 3c to which the bobbin 2 is wound and the sea filament force of the filament is inserted. By dissolving and filamenting filaments from a krill portion made up of a plurality of krills 1 rotated about a rotation axis by winding them in a winder 5 to fabricate the filaments, each of the krills 1 is electric By installing the sea tension tension adjustment mechanism 6 is characterized in that to control the rotational speed of the krill (1) so that the sea tension of the filament can be maintained constant.

In the present invention, the electric sea tension control mechanism 6 is a mechanism for measuring the sea tension of the filament to be seared and the brakes for controlling the rotational speed of the rotating krill by sea sea tension, both of which operate by electric force. When above a certain tension, it is defined as a maritime tension control mechanism in which the brake is operated.

1 is a schematic diagram of the present invention, Figure 2 is a schematic diagram of the electric maritime tension control mechanism installed in the krill of FIG.

In the present invention, it is preferable to provide the guide rollers 4a and 4b between the driver rollers 3a, 3b and 3c and the winding roller 5.

Looking at an example of the electric sea tension control mechanism 6, as shown in Figure 2, after detecting the sea tension of the filament with the sensor (6a) and the detected sea tension and the sea tension tension pre-input from the controller (6b) After calculating the correction value by comparison, the bobbin inserted into the krill according to the correction value is transmitted to the brake 6c for controlling the speed at which the bobbin is rotated by the maritime tension.

When the maritime tension detected by the sensor 6a is higher than the pre-input maritime tension, the braking level of the brake 6c is weakened and the rotation of the bobbin 2, which is inserted into the krill 1 and rotates with maritime tension, becomes free. The filament wound in (2) dissolves faster, which lowers the sea tension.

On the contrary, when the sea force is lower than the previously input sea tension, the braking level of the brake 6c becomes strong, and the bobbin 2 rotating to the sea tension is not freed by being inserted into the krill 1 and the bobbin 2 becomes free. The rolled filaments dissolve more slowly, which results in higher sea power.

As an example of the electric sea tension control mechanism 6, a powder brake or the like may be used.

On the other hand, in the present invention, powder brake is a kind of electric brake in which both the measuring mechanism of the sea tension of the filament to be dissociated and the brake which controls the rotational speed of the rotating krill by the sea tension are operated by electric force. It is defined as a maritime tension control mechanism that is a friction clutch method.

Looking at an example of the powder brake maritime tension control mechanism, as shown in Figure 2 calculates the correction value by comparing the maritime tension measured in advance in the controller 6b, and then inserted into the creel according to the correction value After controlling the speed at which the bobbin is rotated by the sea tension, or by installing the detection sensor 6a to detect the sea tension of the industrial filament, the detected sea tension is pre-injected by the controller 6b in the same way as the former. (6c).

Rotation of the bobbin 2 which is inserted into the krill 1 and rotates to the maritime tension because the powder brake 6c maintains the state of not holding the krill 1 when the maritime tension detected by the sensor 6e is too high. This free and filament wound on the bobbin 2 dissolves faster, which lowers the sea tension.

On the contrary, when the coastal force detected by the sensor 6e is too low, the powder brake 6c momentarily holds the krill 1 and is inserted into the krill 1 so that the rotation of the bobbin 2 rotates with maritime tension. The filaments wound on the bobbin (2) are dissolved more slowly, which leads to higher sea power.

It is more preferable that each of the krill 1 and the winder 5 is attached with a guide for tension adjustment.

The driver rollers 3a, 3b, and 3c are preferably provided with a filament length measuring mechanism and a system capable of smoothly starting and stopping.

The filaments are wholly aromatic polyamide filaments and the like.

The filament thickening method according to the present invention provides a plurality of strands of filaments by providing an electric sea tension tension control mechanism 6 for uniformly controlling the sea power of each filament constituting the plywood filament bundle in each krill 1. It is possible to manufacture a bundle of filament filaments by dissolving them in a uniform sea-power and winding them together in a lead-free state.

Therefore, a part of the filaments constituting the filament bundle filaments produced by the present invention during post-processing, such as fiber covering, does not cause a partial slump due to the tension deviation, and the lead-free high modulus and the fiber covering Expresses the effect of widening the surface area.

According to the present invention, the filaments can be spun and wound in a lead-free state by dissolving several filaments with a uniform sea force, so that a part of the filaments constituting the filament yarn bundles for post-processing sag due to tension deviation sag. Can be effectively prevented.

Therefore, the present invention is useful for producing a bundle of wholly aromatic polyamide filaments used to cover an optical fiber in the manufacture of optical cables.

Claims (7)

The filament is wound from a creel section consisting of a plurality of krills (1) rotated about the axis of rotation by the filament's sea force by inserting a bobbin (2) wound with a filament by using a plurality of driver rollers (3a, 3b, 3c). After dismantling and pulverizing them, and winding them in the winder (5) to make the filament, the sea tension of the filament can be maintained constant by installing an electric sea tension tension mechanism (6) in each of the krill (1) How to adjust the rotation speed of the krill (1) so that the degree of filament. The electric nautical tension adjusting mechanism (6) calculates a correction value by detecting the nautical tension of the filament with a sensor (6a) and then comparing the detected nautical tension with a nautical tension previously input from the controller (6b). And then transfer it to the brake 6c which controls the speed at which the bobbin inserted into the krill is rotated by maritime tension according to the correction value. The method of claim 1 wherein the filament is a wholly aromatic polyamide filament. The method of claim 1, wherein the driver rollers (3a, 3b, 3c) are equipped with a filament length measuring mechanism and a slow start and stop system. 2. Method according to claim 1, characterized in that the electric sea tension control mechanism (6) is a powder brake. The method of claim 1, wherein the tension adjustment guide is attached to the krill (1) and the winder (5). The powder brake calculates a correction value by comparing the sea tension to a sea level tension previously measured at the controller 6b, and then, the bobbin inserted into the krill is rotated by the sea tension. After controlling the speed or installing a detection sensor (6a) to detect the sea tension of the industrial filament, the detected sea tension is transmitted to the powder brake (6c) previously input from the controller (6b) as in the former The method of drawing up the filament.

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