KR20110018029A - Interlacing device for winding multi-end filament - Google Patents

Abstract

PURPOSE: An interlacing device used in winding process for multi-end fiber filament is provided to shorten rewinding time and to improve productivity. CONSTITUTION: An interlacing device(100) comprises: a path(111) for passing a filament, and an air guide device(112) formed on the path. The air guide device spirally guides the air along the extension direction of the path. The air guide device is a screw thread formed along the extension direction of the path on the inner wall of the path. The air guide device is formed more than 10mm along the extension direction of the path. The interlacing device further comprises at least one inlet holes(113a, 113b).

Description

Winding entanglement device for multi-end fiber filaments {INTERLACING DEVICE FOR WINDING MULTI-END FILAMENT}

The present invention relates to a entanglement device, and more particularly, to an entanglement device for use in a winding process of a multi-end fiber filament.

Conventional entanglement device is used for fine denier, and is used to give uniform entanglement of synthetic fiber filament such as nylon and polyethylene terephthalate (PET) at high speed of 3000m / min or more in order to improve the appearance of yarn and workability during post processing. have.

On the other hand, when winding two or more multi-end fiber filaments, each filament is wound independently of the winder. If a threaded filament occurs, the threaded filament should be connected to the winding machine and rewound. This rewinding operation takes a lot of time and requires improvement.

It is an object of the present invention to provide a entanglement device for winding which can increase the spinning yield and productivity in the production of synthetic fibers.

In order to achieve the above object, according to an aspect of the present invention,

And a passage formed to pass the filament, and air guide means formed on the passage, wherein the air guide means spirally guides air along an extending direction of the passage.

The air guide means may be a screw thread formed along the extending direction of the passage on the inner wall surface of the passage.

The air guide means may be formed at least 10mm along the extending direction of the passage.

The entanglement device further includes at least one inlet for providing compressed air to the passage, and the pressure of the compressed air provided through the inlet may be 10 kgf / cm ^{2 or} more.

The entanglement device may further comprise two or more inlets for providing compressed air to the passageway.

The entanglement device further includes at least one inlet for providing compressed air to the passage, wherein the compressed air injected from the inlet may have a flow component that is rotated by a screw thread toward the passage direction of the filament.

The passage can pass together the filament being wound and the filament being trimmed.

According to the configuration of the present invention can achieve the object of the present invention described above. Specifically, the filament trimmed by the entanglement device to guide the flow of compressed air spirally moves to the winder in a state that is strongly entangled in the filament being wound, so it is suitable for the thick denier, and the rewinding time is shortened and the productivity is reduced. This is improved.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of an embodiment according to the present invention.

1 is a perspective view of an entanglement device according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the entanglement device shown in FIG. 1 taken along line A-A. FIG. 3 is a view showing a state of two filaments entangled by the entanglement device shown in FIG. 1, and FIG. 4 is a view schematically showing a process of winding a two-end filament using the entanglement device shown in FIG. to be.

First, the configuration of an embodiment according to the present invention will be described in detail.

1 and 2, the entanglement device 100 includes a body 110 and first and second compressed air supply pipes 120a and 120b connected to the body 110. The entanglement device 100 entangles the filament being wound and the filament which has been trimmed.

The body 110 includes a passage 111, an air guide means 112, first and second inlets 113a and 113b, and a filament introduction portion 114.

The passage 111 extends along the extension axis X and has a circular cross section. Both ends of the passage 111 in the extension axis X direction are open to form an inlet 111a and an outlet 111b, respectively. Two filaments to be entangled pass through the passage 111 from the inlet 111a to the outlet 111b, and the two filaments are entangled in the passage 111.

The air guide means 112 is a screw thread formed extending in the extending direction of the passage 111 on the inner wall surface 111c of the passage 111. The air guide means 112 has a peak 112a and a valley 112b. Most of the compressed air provided to the passage 111 rotates along the valley portion 112b of the air guide means 112 and flows in the extension axis X direction. Although the air guide means 112 is shown in the figure formed in the entire area of the passage 111, the present invention is not limited thereto. The air guiding means 112 may be formed only in some regions of the passage 111, as shown, and such examples are included in the scope of the present invention. The length L in the extension axis X direction of the air guide means 112 is preferably 10 mm or more. If the air guiding means 112 is formed to be shorter than 10 mm, the strength of sufficient entanglement cannot be obtained. In the present embodiment, the air guide means 112 is described as being in the form of a screw thread, but the present invention is not limited thereto. The air guiding means can be any type that can guide the compressed air to flow helically in the passage (111). For example, the helical groove may be formed on the inner wall surface 111c of the passage 111 to form the air guide means.

The first inlet 113a and the second inlet 113b are holes formed on the inner surface 111c of the passage 111. Compressed air is introduced into the passage 111 through the first inlet 113a and the second inlet 113b. The first inlet 113a and the second inlet 113b are located close to the inlet 111a side of the passage 111. This is to increase the length between the two inlets 113a and 113b and the outlet 111b of the passage 111 as much as possible to increase the length of the section affected by the compressed air. The first inlet 113a and the second inlet 113b are preferably located opposite to each other on the passage 111 as shown. That is, the first inlet 113a and the second inlet 113b are located at positions symmetrical with respect to the centerline of the passage 111. Accordingly, since the air A1 introduced from the first inlet 113a and the air A2 introduced from the second inlet 113b are injected toward the center of the passage 111 from the opposite side, the entanglement efficiency is increased. In the present exemplary embodiment, two inlets are described, but the present invention is not limited thereto. One or three or more inlets may be provided, which is also included in the scope of the present invention.

The first connection passage 113a1 and the second connection passage 113b1 formed in the body 110 are connected to the first inlet 113a and the second inlet 113b, respectively. The first connecting passage 113a1 and the second connecting passage 113b1 extend along the radial direction of the passage 111 and are inclined with respect to the extension axis X so as to approach the outlet 111b toward the passage 111. . Therefore, the compressed air A1 injected from the first inlet 113a to the passage 111 and the compressed air A2 injected from the second inlet 113b to the passage 111 are the outlet 111b of the passage 111. It will have a flow component towards). Accordingly, the compressed air can flow strongly toward the outlet 111b in the passage 111.

The filament inlet 114 is a passage connecting the outside of the passage 111 and the body 110. The filament introduction portion 114 has a slit shape formed extending from the inner wall surface 111c of the passage 111 along the radial direction of the passage 111. The filament inlet 114 is formed from the inlet 111a to the outlet 111b of the passage 111. The filament to be entangled through the filament introduction part 114 is received in the passage 111 of the entanglement device 100.

The first compressed air supply pipe 120a and the second compressed air supply pipe 120b are coupled to the body 110. The first internal passage 121a provided in the first compressed air supply pipe 120a is connected to the first connection passage 113a1 of the body 110 to form a passage of the compressed air. The second internal passage 121b provided in the second compressed air supply pipe 120b is connected to the second connection passage 113b1 of the body 110 to form a passage of compressed air. The first compressed air supply pipe 120a and the second compressed air supply pipe 120b are connected to a pump (not shown) that generates compressed air. The compressed air generated by the pump is provided to the entanglement device 100 through the first compressed air supply pipe 120a and the second compressed air supply pipe 120b.

The operation of the above embodiment will now be described in detail with reference to FIGS. 1 to 4.

When a threaded filament occurs during winding of the multi-end filament, the second filament 10b that has been trimmed with the first filament 10a being wound is provided to the interlock device 100. The first filament 10a and the second filament 10b are received in the passage 111 through the filament introduction portion 114 of the entanglement device 100. In this state, the compressed air is supplied to the body 110 through the first compressed air supply pipe 120a and the second compressed air supply pipe 120b. The compressed air supplied to the body 110 flows into the passage 111 through the first inlet 113a and the second inlet 113b after passing through the first connection passage 113b1 and the second connection passage 113b2, respectively. . At this time, since the first connecting passage 113a1 and the second connecting passage 113b1 are inclined toward the outlet 111b toward the center with respect to the extension axis X of the passage 111, the first connecting passage 113a1. In the compressed air (A1) flowing into the passage 111 and the compressed air (A2) flowing into the passage 111 in the second connecting passage (113b1) has a flow component toward the outlet (111b). Accordingly, the compressed air introduced into the passage 111 can maintain a strong flow toward the outlet 111b. In addition, since the first inlet 113a and the second inlet 113b are located opposite to each other, two compressed air A1 and A2 injected from each of the inlets 113a and 113b meet strongly at the center of the passage 111. The entanglement of the two filaments 10a, 10b can be made efficiently.

The compressed air introduced into the passage 111 through the first inlet 113a and the second inlet 113b rotates helically along the valley 120b of the air guide means 120 and moves toward the outlet 111b. do. By the flow of compressed air, the first filament 10a and the second filament 10b are twisted in a knot shape while being rotated and strongly entangled. The entanglement filaments 10c, which are entangled and joined together from the entanglement device 100, enter the separation device 200. Although not shown, the separator 200 includes a suction gun and a guide part. The entangled filament 10c is sucked and moved through the suction unit, and then separated into two filaments 10d and 10e through the guide. The two filaments 10d and 10e separated by the separating device 200 are provided to the winder 300 and wound up.

Table 1 shows test data comparing the entanglement device according to the embodiment with a conventional entanglement device without threads. The fiber used in the test is para-polyterephthalamide having an intrinsic viscosity of at least 4.5. As shown in Table 1, the entanglement device according to the embodiment of the present invention provides much stronger strength to the entangled portion than the conventional entanglement device. In addition, the strongest entanglement can be seen in the conditions of the spinning speed 500m / min, thread forming length 20mm, air pressure 18 kgf / cm ² of the various embodiments according to the change of the spinning speed, thread length, air pressure have.

Spinning speed
(m / mim) High Pressure Air Discharge Part
Thread Forming Length (L) (mm) Air pressure
(kgf / cm ² ) Gangway strong
(kgf / cm ² ) Example 1 500 10 10 15 Example 2 500 15 10 18 Example 3 500 15 15 20 Example 4 500 20 18 24 Example 5 600 20 18 22 Comparative Example 1 500 - 5 - Comparative Example 2 500 - 10 8 Comparative Example 3 500 - 15 14 Comparative Example 4 600 - 15 11

The present invention has been described above with reference to the above embodiments, but the present invention is not limited thereto. Those skilled in the art will appreciate that modifications and changes can be made without departing from the spirit and scope of the present invention and that such modifications and changes also belong to the present invention.

1 is a perspective view of an entanglement device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the interlock device shown in FIG. 1 taken along line A-A.

3 is a view showing a state of two filaments entangled by the entanglement device shown in FIG.

4 is a view schematically showing a process of winding a two-end filament using the entanglement device shown in FIG.

<Explanation of symbols for the main parts of the drawings>

10a: first filament 10b: second filament

100: entanglement device 110: body

111 passage 112 air guide means

113a: first inlet 113b: second inlet

114: filament inlet

Claims (7)

A passage formed through the filament, Air guide means formed on the passageway; The air guide means is entangled device, characterized in that for guiding the air spirally along the extending direction of the passage. The method of claim 1, And the air guide means is a screw thread formed along an extending direction of the passage on an inner wall surface of the passage. The method of claim 1, The air guide device is characterized in that the entanglement device is formed 10mm or more along the extending direction of the passage. The method of claim 1, At least one inlet for providing compressed air to the passageway, The pressure of the compressed air provided through the inlet is entangled device, characterized in that more than 10kgf / cm ² . The method of claim 1, An entanglement device further comprising two or more inlets for providing compressed air to the passageway. The method of claim 1, At least one inlet for providing compressed air to the passageway, Compressed air injected from the inlet has a flow component which is directed toward the passage direction of the filament. The method of claim 1, The passageway includes a first filament being wound and a second filament which has been trimmed pass together.

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