KR102754550B1 - Wet drawing machine for fishing line - Google Patents

Abstract

The present invention relates to a wet fishing line drawing device. Specifically, the present invention relates to a fishing line wet drawing device for a wet drawing process in fishing line production, and comprises a drawing tank filled with high-temperature water for a wet drawing process, wherein the fishing line wet drawing device comprises a drawing tank immersion sponge formed at the inlet and outlet of the drawing tank and absorbing the high-temperature water in the drawing tank to immerse passing fibers, a plurality of heater rods for heating the water in the drawing tank, an air bubble for firing air in the drawing tank to cause the surface of the high-temperature water to ripple, a siphon part for condensing water vapor generated in the drawing tank and supplying it back into the drawing tank, and a cover part for covering the top of the drawing tank, the inner top surface of which is formed to be inclined so that water vapor flows along the inclined surface, and a cover immersion sponge interlocked with the drawing tank immersion sponge is provided in the direction of the inlet and the outlet, and the siphon part comprises a condensation tank for collecting condensed water, and a cover part for condensing refrigerant from a side wall of the condensation tank. It is configured to further include a refrigerant pipe provided as a flowing pipe and a siphon pipe that re-supplies the condensate collected in the condensation tank toward the high temperature water using the siphon principle.

Description

Wet drawing machine for fishing line

The present invention relates to a wet drawing device for fishing line, and more particularly, to a wet drawing device for fishing line for a wet drawing process in fishing line production.

The steps for manufacturing fibers can be broadly divided into the stages of polymerization, spinning, drawing, and twisting.

Polymerization refers to the process in which monomers are joined together to form a large molecule. There is addition polymerization, in which the same type of monomer with an unsaturated group grows, and condensation polymerization, in which a monomer with two functional groups grows by removing a simple compound between the terminal groups.

And, spinning is a method of dissolving or melting a polymer and extruding it into a fiber through a spinneret. There are wet spinning, which dissolves a polymer in a solvent to make a spinning solution, extrudes it through a spinneret into a coagulating bath, and solidifies it into a fiber, dry spinning, which dissolves a polymer in a solvent to make a spinning solution, extrudes it into the air, and solidifies it by volatilizing the solvent, and melt spinning, which extrudes a melt through a nozzle and solidifies it into a fiber when a polymer does not decompose even when heated above its melting point.

And, drawing refers to the rearrangement of molecules while being wound from a slow-rotating feed roller to a fast-rotating take-up roller. Polymer materials are generally solid, but their mechanical properties are greatly affected by the orientation of the polymer chains. If a polymer in an unoriented state is pulled in a certain direction above the second transition temperature, the polymer chains will be oriented in the direction of the pull and its mechanical properties will change. A relaxation operation is called drawing, and the spun synthetic filament can be easily stretched even with a very small force, and the stretched filament will not return to its original state even when the tension is removed. This is because the polymers are in an amorphous state. Therefore, this in itself is not practical as a fiber, but if pulled above the second transition temperature, the molecules will be oriented in the direction of the fiber axis, becoming a fiber with excellent elasticity.

And, false twist is a processing method that gives bulkiness to the yarn by twisting and then releasing a synthetic filament with heat setting properties at high speed while performing contact heat treatment.

The process of manufacturing fishing line fibers includes a drawing process. The general fishing line manufacturing process is made up of spinning-cooling-wet-dry-heat treatment, and depending on the technology of each company, there are cases where it is all wet and cases where it is all dry. The present invention relates to a wet drawing device and includes a wet drawing process.

In the case of the wet drawing process, since the drawing is done wet, if the fibers are not sufficiently immersed, differences in the fiber drawing portion may occur. Since the fibers are spun to produce multiple products at once, not just one, the crystalline and amorphous orientations must occur at the same speed. If the drawing portions differ due to differences in amorphous formation in a situation where immersion is not sufficient, the molecular arrangement of each strand will be different, resulting in uneven product quality and differences in physical properties. Therefore, sufficient immersion is essential for the drawing process.

Looking at the general wet drawing process, in order to sufficiently immerse the fibers, they are immersed through multiple rollers in the drawing tank. In other words, the fibers pass directly through the high-temperature water in the drawing tank through the rollers. However, the process of passing through multiple rollers while applying tensile force to the fibers causes damage to the surface of the fibers, which ultimately leads to a decrease in quality. Therefore, it is necessary to develop a technology that can achieve sufficient immersion while minimizing damage to the fibers.

Meanwhile, the wet stretching process uses high-temperature water of 80 to 100℃, and there was a problem that water had to be continuously supplied because the high-temperature water continuously evaporated. In addition, when new water was supplied, additional heat energy was required to heat the supplied water, so there was a serious problem of energy consumption.

The prior art Korean Patent No. 10-1551419 relates to an effective drawing method for polyketone fibers, and provides a configuration for achieving a drawing process using a roller heating type drawing machine as shown in Fig. 1. However, since drawing occurs through rollers in a drawing tank, as described above, it is difficult to minimize damage to the fibers caused by the rollers.

Republic of Korea Patent No. 10-1551419

The present invention is intended to solve the above-mentioned problems, and its purpose is to prevent damage to the fiber by the roller in the drawing tank in the wet drawing process of a fishing line.

Another object of the present invention is to provide a drawing device capable of reducing the amount consumed due to evaporation of high-temperature water in a drawing tank, thereby reducing water waste and energy for heating newly added water.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems to be solved by the present invention that are not mentioned herein will be clearly understood by a person having ordinary skill in the art to which the present invention belongs from the description below.

In order to solve the above-mentioned problem, the wet drawing device of the present invention comprises a drawing tank filled with high-temperature water for a wet drawing process, wherein the wet drawing device comprises a drawing tank immersion sponge formed at the inlet and outlet of the drawing tank and absorbing the high-temperature water in the drawing tank to immerse a passing fiber, a plurality of heater rods for heating the water in the drawing tank, an air bubble for firing air in the drawing tank to cause the surface of the high-temperature water to ripple, a siphon section for condensing water vapor generated in the drawing tank and supplying it back into the drawing tank, and a cover section for covering the top of the drawing tank, the inner top surface of which is formed to be inclined so that the water vapor flows along the inclined surface, and a cover section in which a cover immersion sponge interlocked with the drawing tank immersion sponge is provided in the direction of the inlet and outlet, the siphon section comprises a condensation tank for collecting condensed water, a refrigerant pipe provided as a pipe through which a refrigerant flows on a side wall of the condensation tank, It is configured to further include a siphon pipe that re-supplies the condensate collected in the above condensation tank toward the high temperature water using the siphon principle.

Preferably, the method may include providing a front guide roller in front of the entrance of the elongation tank and a rear guide roller in the rear of the exit, and including forming a plurality of protrusions along the circumferential direction on the outer surfaces of the front guide roller and the rear guide roller to guide the fibers so that they are fed into the elongation tank without being entangled with each other.

Preferably, a moisture absorber is further provided between the elongation tank outlet and the rear guide roller, and the moisture absorber may include a plurality of absorption grooves formed through which the fibers pass, and an absorption hole formed in the absorption grooves for absorbing moisture.

Preferably, the air gun further includes a circular fixed plate fixedly installed on a side wall of a stretching tank, a launcher formed in the shape of a ball valve at the center of the fixed plate so as to be angle-adjustable and having a diameter that narrows toward a launcher, and a shielding plate provided in the shape of a disc that rotates between the fixed plate and the side wall of the stretching tank, wherein the launcher fires air upward at a predetermined angle to maximize ripples on the surface of high-temperature water, and the shielding plate may include a part of the disc that is open so that compressed air transmitted from a compressor is fired through the launcher at predetermined intervals according to the rotation cycle of the shielding plate.

Preferably, a guide projection protrudes downward on the inner side of the cover portion to guide the condensed water vapor toward the condensation tank, and the guide projection may be formed in a cone shape that narrows downward.

The wet drawing device for fishing line according to the present invention has the effect of preventing damage to the fibers by the rollers by forming a drawing section through which the fibers pass between the drawing tank immersion sponge and the cover immersion sponge.

The wet fishing line drawing device according to the present invention reduces water waste by re-supplying water evaporated through the siphon section into the drawing tank, and reduces heat energy use by supplying lukewarm water through the siphon section.

Figure 1 illustrates an example of a prior art in which a fiber is stretched through a roller in a stretching tank.
Figure 2 is an example showing the entire fishing line fiber yarn stretching process of a fishing line wet stretching device according to the present invention.
Figure 3 is an example showing a drawing tank and a cover part of a wet drawing device for fishing line according to the present invention, and a drawing tank immersion sponge and a cover immersion sponge.
FIG. 4 is an example showing the inside of a stretching tank of a wet fishing line stretching device according to the present invention, showing the shape of the inner top surface of the cover part, along with high-temperature water, a siphon part, and an air bubble.
FIG. 5 is an example showing a wet fishing line drawing device according to the present invention in which high-temperature water evaporates and water vapor moves along the upper surface of the cover to the siphon section to become condensed water.
FIG. 6 is an enlarged example showing a wet fishing line drawing device according to the present invention in which water vapor is condensed and collected in a condensation tank.
Fig. 7 is an example showing that condensed water escapes through a siphon tube by the siphon principle in a wet fishing line drawing device according to the present invention.

The advantages and features of the present invention, and the method for achieving them, will become clear with reference to the embodiments described in detail below together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and these embodiments are provided only to make the disclosure of the present invention complete, and to fully inform a person having ordinary skill in the art to which the present invention belongs of the scope of the invention. In addition, the terminology used in this specification is for the purpose of describing the embodiments, and is not intended to limit the present invention. In this specification, the singular includes the plural unless specifically stated in the phrase.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the attached drawings. Meanwhile, the structure and its operation and effect, which can be easily understood by those with ordinary knowledge in the relevant technical field, will be briefly described or omitted, and the parts related to the present invention will be described in detail.

First, a description of a drawing of a wet fishing line drawing device according to the present invention is as follows.

Figure 2 is an example showing the entire fishing line fiber yarn stretching process of a fishing line wet stretching device according to the present invention.

And, Fig. 3 is an example showing a stretching tank and a cover part of a wet stretching device for fishing line according to the present invention, and a stretching tank immersion sponge and a cover immersion sponge.

In addition, Fig. 4 is an example showing the inside of a stretching tank of a wet fishing line stretching device according to the present invention, showing the shape of the inner top surface of the cover part, along with high-temperature water, a siphon part, and an air bubble.

In addition, Fig. 5 is an example showing that, in a wet fishing line drawing device according to the present invention, high-temperature water evaporates and water vapor moves along the upper surface of the cover to the siphon section to become condensed water.

In addition, FIG. 6 is an example showing an enlarged view of a wet fishing line drawing device according to the present invention, in which water vapor is condensed and collected in a condensation tank.

And, Fig. 7 is an example showing that condensed water escapes through a siphon tube by the siphon principle in a wet fishing line drawing device according to the present invention.

The wet drawing device for a fishing line according to the present invention comprises a drawing tank (1) filled with high-temperature water for a wet drawing process, as shown in FIGS. 2 to 7, wherein the wet drawing device comprises a drawing tank immersion sponge (11) formed at the inlet and outlet of the drawing tank (1) and absorbing high-temperature water (B) in the drawing tank (1) to immerse a passing fiber (A), a plurality of heater rods for heating the water in the drawing tank (1), an air bubble (4) for firing air in the drawing tank (1) to cause the surface of the high-temperature water (B) to ripple, a siphon part (3) for condensing water vapor generated in the drawing tank (1) and supplying it back into the drawing tank (1), and a cover covering the top of the drawing tank (1), the inner top surface of which is formed to be inclined so that water vapor flows along the inclined surface, and a plurality of heating rods for heating the water in the drawing tank (1) are provided. It includes a cover part (2) provided with a cover immersion sponge (21) that is interlocked with an immersion sponge (11), and the siphon part (3) may further include a condensation tank (31) that collects condensate (C), a refrigerant pipe (32) provided as a pipe through which refrigerant flows on the side wall of the condensation tank (31), and a siphon pipe (33) that re-supplies the condensate (C) collected in the condensation tank (31) toward the high temperature water (B) using the siphon principle.

First, as shown in FIGS. 2 to 4, a drawing tank (1) is provided in the present invention for a wet drawing process. The drawing tank (1) is a tank filled with high-temperature water (B), and is used to immerse fibers (A) by filling it with water of 80 to 100°C.

As shown in Fig. 3, the elongation tank immersion sponge (11) is formed at the inlet and outlet of the elongation tank (1) and serves to absorb high temperature water (B) in the elongation tank (1) and immerse the passing fiber (A).

Specifically, as shown in Fig. 2, the elongation tank immersion sponge (11) is provided at the upper end of the front and rear of the elongation tank (1) where the fiber (A) is fed and discharged, and absorbs the high-temperature water (B) inside the elongation tank (1). The fiber (A) sweeps over the upper surface of the elongation tank immersion sponge (11).

More specifically, as shown in Fig. 3, the elongation tank immersion sponge (11) is interlocked with the cover immersion sponge (21) of the cover part (2), and the fiber (A) passes between the interlocking points. That is, the fiber (A) passes while being caught between the elongation tank immersion sponge (11) and the cover immersion sponge (21), so that immersion in the high-temperature water (B) from all sides is achieved.

In addition, the plurality of heater rods can play a role in heating water within the elongation tank (1). The heater rods may be provided in any shape as long as they have a structure capable of heating water within the elongation tank (1) to a preset temperature.

In addition, as shown in Fig. 4, the air bubble (4) can fire air within the elongation tank (1) to cause the surface of the high-temperature water (B) to ripple.

The wet drawing device for fishing line according to the present invention does not deeply immerse the fiber (A) into a tank using a roller, but can produce the same effect as immersing the fiber (A) through the drawing tank immersion sponge (11) and the cover immersion sponge (21). In addition, this method can prevent the fiber (A) from being damaged by the roller.

In addition, when the air bubble (4) fires air to cause the surface of the high-temperature water (B) to ripple, the high-temperature water (B) comes into contact with the fiber (A) passing through the drawing tank (1), causing immersion.

The above air bubbles (4) can maximize the ripples on the surface of the high-temperature water (B) by firing air at a certain angle upward. This is to ensure that the ripples of the high-temperature water (B) evenly reach the entire fiber (A) by directing the firing angle of the air bubbles (4) upward at a certain angle.

In more detail, the air gun (4) may further include a circular fixed plate fixedly installed on the side wall of the elongation tank (1), a launcher formed in the shape of a ball valve at the center of the fixed plate so as to be angle-adjustable and having a diameter that narrows toward the launcher, and a shielding plate provided in the shape of a disc that rotates between the fixed plate and the side wall of the elongation tank (1).

The above launcher can maximize the ripples on the surface of the high temperature water (B) by firing air upward at a certain angle. Since the launch angle is controlled by the flow of the launcher, customized launch angle control is possible according to the high temperature water (B) level.

Additionally, the launcher has a diameter that narrows toward the launcher, allowing it to fire air at a stronger pressure.

In addition, the shield plate has a part of the disc open so that compressed air delivered from the compressor can be fired through the launcher at regular intervals according to the rotation cycle of the shield plate. That is, by controlling the rotation speed of the rotating plate, the interval of air fired by the air bubble (4) can be controlled, and the high-temperature water (B) can be controlled so that it can sufficiently reach the fiber (A) without overflowing the elongation tank (1).

Next, as shown in FIGS. 5 to 7, the siphon section (3) can condense the water vapor generated within the elongation tank (1) and supply it back into the elongation tank (1).

Specifically, the siphon section (3) may be configured to include a condensation tank (31), a refrigerant pipe (32), and a siphon pipe (33).

The above condensation tank (31) serves as a water receiving space where condensation water (C) is collected and stored. In addition, the above condensation tank (31) is provided on the side wall of the extension tank (1), but is formed at a higher location than the location of the high-temperature water (B).

In addition, the refrigerant pipe (32) is provided as a pipe through which refrigerant flows on the side wall of the condensation tank (31) to condense the vaporized high-temperature water (B) and collect it again in the condensation tank (31).

In addition, the siphon pipe (33) serves to re-supply the condensed water (C) collected in the condensation tank (31) toward the high temperature water (B) using the siphon principle.

And, the cover part (2) is provided as a cover covering the upper part of the elongation tank (1), and the inner upper surface is formed to be inclined so that water vapor flows along the inclined surface, and a cover immersion sponge (21) interlocked with the elongation tank immersion sponge (11) is provided in the inlet and outlet directions.

For a more detailed explanation, as shown in FIGS. 4 and 5, the inner top surface of the cover part (2) has a roof-like shape and a triangle shape with a pointed center. That is, as the high-temperature water (B) vapor rises, it hits the inner top surface of the cover part (2), and some of the condensation or vapor moves along the top surface to both sides. At this time, the siphon part (3) is provided on the side.

As shown in FIGS. 5 and 6, the siphon section (3) includes a condensation tank (31) and a refrigerant pipe (32), and through temperature exchange with the refrigerant, the water vapor condenses into water droplets and falls and collects in the condensation tank (31). At this time, the refrigerant may be cold water, but any refrigerant may be used as long as it can condense the water vapor through heat exchange.

The condensed water (C) that has condensed into water is returned to the high temperature water (B) location by the siphon pipe (33).

As shown in Fig. 7, the siphon tube (33) is made of a narrow tube, one side of which is positioned inside the condensation tank (31), and the other side is positioned toward the high-temperature water (B). Therefore, when the condensation water (C) gathers above a certain height, the condensation water (C) in the condensation tank (31) moves toward the high-temperature water (B) due to the pressure difference by the siphon principle.

The amount of water that is evaporated and consumed can be minimized through the siphon tube (33) of the present invention. In addition, since only a phase change from water vapor to water droplets occurs, it falls into the condensation tank (31), and thus has a higher temperature than the water newly supplied to the extension tank (1). In other words, since the heat energy used by the heater rod to heat water is reduced, the waste of heat energy by the heater rod can be minimized.

At the same time, the refrigerant pipe (32) performs heat exchange through the side wall of the condensation tank (31), so that the condensation tank (31) itself acts as a kind of barrier, minimizing the temperature effect on the high-temperature water (B) contained in the extension tank (1). In other words, the temperature of the high-temperature water (B) can be continuously maintained while using less heat energy.

In addition, the siphon tube (33) utilizes the siphon principle, and the siphon principle or siphon phenomenon refers to a connecting tube that is made to move liquid from a high place to a low place using pressure difference and gravity. If the inside of the siphon tube (33) is full of liquid, the liquid is sucked out by the siphon principle, and this phenomenon is called the siphon effect. According to Bernoulli's principle, the pressure of a fluid that moves quickly decreases. Then, the pressure inside the siphon tube (33) will decrease, and since the pressure of the condensed water (C) existing in the condensation tank (31) is relatively high, the condensed water (C) is sucked into the siphon tube (33). If this process continues continuously, and the pressure inside the siphon tube (33) is maintained lower than the atmospheric pressure in the condensation tank (31), the condensed water (C) will continue to flow along the siphon tube (33) without stopping until it has completely moved toward the high-temperature water (B).

And, as shown in Fig. 2, a front guide roller (5) is provided in front of the entrance of the extension tank (1).

The above guide rollers enable the fibers (A) to be fed into the inlet of the drawing tank (1) without being tangled. Similarly, a rear guide roller (6) is provided at the rear of the exit of the drawing tank (1). That is, the front guide roller (5) and the rear guide roller (6) can serve to guide the direction of the fibers (A) fed into and discharged from the drawing tank (1).

In more detail, a plurality of protrusions are formed along the circumferential direction on the outer surface of the front guide roller (5) and the rear guide roller (6) so as to guide the fibers (A) to be fed into the drawing tank (1) without being entangled with each other.

In addition, as shown in Fig. 2, a moisture absorber (7) may be additionally provided between the outlet of the extension tank (1) and the rear guide roller (6).

Preferably, a moisture absorber (7) is further provided between the outlet of the extension tank (1) and the rear guide roller (6), and the moisture absorber (7) may include a plurality of absorption grooves formed through which the fibers pass, and an absorption hole formed in the absorption grooves to absorb moisture.

In addition, a moisture absorbing cloth may be additionally provided on the top of the moisture absorber (7) in the form of covering the moisture absorber (7). As the fiber (A) passing through the stretching tank (1) passes between the moisture absorber (7) and the moisture absorbing cloth, the moisture above the fiber (A) is absorbed by the moisture absorbing cloth and the moisture below is removed by the moisture absorber (7), so that the moisture on the surface of the fiber (A) can be removed more effectively.

Meanwhile, a guide protrusion may be further formed on the cover portion (2).

The above guide projection is formed at the end of the inner side of the cover part (2) and can guide the water vapor condensed into water droplets toward the condensation tank (31). That is, even if the water vapor condenses into water droplets before being collected in the condensation tank (31), it flows along the inner structure of the cover part (2) and moves to the top of the condensation tank (31), and can be collected as condensed water (C) by falling into the condensation tank (31) through the guide projection and being purified.

In addition, the above guide protrusion is formed in a cone shape that narrows downwards to concentrate downwards so that the condensate (C) can fall accurately into the condensate tank (31).

As described above and illustrated in FIGS. 2 to 7, suitable embodiments of the wet fishing line drawing device according to the present invention are as follows.

First, the fishing line fiber (A) is guided by the front guide roller (5) and fed into the drawing tank (1). At this time, the fiber (A) is immersed in the high-temperature water (B) by the drawing tank immersion sponge (11) and the cover sponge. Then, the high-temperature water (B) forms ripples by the air bubbles (4) inside the drawing tank (1), and the high-temperature water (B) is continuously sprayed on the fiber (A), so that an immersion effect passing through the inside of the high-temperature water (B) can be obtained. In addition, as it exits the drawing tank (1), the fiber (A) is immersed again by the immersion sponge and the cover sponge provided at the rear. Then, the moisture in the fiber (A) is removed while passing between the moisture absorber (7) and the moisture absorbing cloth. Next, the fiber (A) is wound on the winding drum (8) through the rear guide roller (6).

While the fiber (A) is immersed through a wet drawing process, water inside the drawing tank (1) becomes high temperature water (B) by the heater rod and evaporation occurs continuously. The generated water vapor flows along the inner upper surface of the cover part (2) and is collected in the siphon part (3) located on the side of the drawing tank (1).

The above siphon section (3) includes a condensation tank (31), a refrigerant pipe (32), and a siphon pipe (33). Heat exchange occurs between the refrigerant and the steam in the refrigerant pipe (32) provided on the side wall of the condensation tank (31), and the steam condenses into condensate (C) and is collected in the condensation tank (31). When the condensate (C) collects above a certain level in the condensation tank (31), the condensate (C) is re-supplied into the extension tank (1) through the siphon pipe (33) by the siphon principle.

In this way, the wet fishing line drawing device according to the present invention does not require a roller provided inside the tank, and since the immersion and drawing of the fiber (A) occurs without passing through the roller, damage to the fiber (A) can be minimized.

In addition, water waste is reduced because the continuously evaporating high-temperature water (B) can be condensed and re-supplied.

In addition, the condensed water (C) is formed at a higher temperature than the water newly supplied to the extension tank (1), so it is expected that the effect of saving heat energy for generating high-temperature water (B) can be expected.

The foregoing has broadly described the features and technical advantages of the present invention so that the scope of the claims to be described later may be better understood. Those skilled in the art will appreciate that the present invention may be implemented in other specific forms without changing the technical idea or essential features thereof. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modifications derived from the claims and their equivalents should be interpreted as being included in the scope of the present invention.

A: Textiles
B: High temperature water
C: Condensation
1: Extension
11: Sponge soaking in the water
2: Cover part
21: Cover soaking sponge
3: Siphon section
31: Condensation tank
32 : Refrigerant pipe
33: Siphon tube
4: Air bubbles
5: Front guide roller
6: Rear guide roller
7: Moisture absorber
8: Winding drum

Claims (5)

A fishing line wet drawing device comprising a drawing tank filled with high temperature water for a wet drawing process,
A drawing tank immersion sponge formed at the entrance and exit of the drawing tank and which absorbs high temperature water in the drawing tank and immerses the passing fibers;
A plurality of heater rods for heating water within the above-mentioned extension tank;
Air bubbles that fire air within the above-mentioned extension tank to cause the surface of the high-temperature water to ripple;
A siphon section that condenses the water vapor generated within the above-mentioned extension tank and supplies it back into the extension tank; and
A cover part is provided as a cover covering the upper part of the above-mentioned stretching tank, the inner upper surface is formed to be inclined so that water vapor flows along the inclined surface, and a cover immersion sponge interlocked with the above-mentioned stretching tank immersion sponge is provided in the direction of the inlet and outlet;
A fishing line wet stretching device characterized in that the above siphon section further includes a condensation tank for collecting condensate, a refrigerant pipe provided as a pipe through which refrigerant flows on the side wall of the condensation tank, and a siphon pipe for resupplying the condensate collected in the condensation tank toward high-temperature water using the siphon principle. In the first paragraph,
Including a front guide roller provided in front of the entrance of the above extension tank and a rear guide roller provided in the rear of the exit,
A wet fishing line drawing device characterized in that a plurality of protrusions are formed along the circumferential direction on the outer surface of the front guide roller and the rear guide roller to guide the fibers so that they are fed into the drawing tank without becoming entangled with each other. In the second paragraph,
A moisture absorber is further provided between the above extension tank outlet and the rear guide roller;
A fishing line wet drawing device characterized in that the above moisture absorber is formed with a plurality of absorption grooves through which fibers pass, and an absorption hole for absorbing moisture is formed in the absorption grooves. In the first paragraph,
The above air gun further includes a circular fixed plate fixedly installed on the side wall of the extension tank, a launcher formed in the shape of a ball valve at the center of the fixed plate so as to be angle-adjustable and having a diameter that narrows toward the launcher, and a shielding plate provided in the shape of a disc that rotates between the fixed plate and the side wall of the extension tank.
The above launcher fires air upward at a certain angle to maximize the ripples on the surface of the hot water.
A wet fishing line drawing device, characterized in that the shielding plate has a part of the disk open so that compressed air delivered from a compressor is fired through the firing tube at regular intervals according to the rotation cycle of the shielding plate. In the first paragraph,
A fishing line wet stretching device characterized in that a guide projection protrudes downward on the inner side of the cover portion to guide condensed water vapor toward the condensation tank, and the guide projection is formed in a cone shape that narrows downward.