KR102697749B1 - Apparatus for manufacturing yarn for artificial turf - Google Patents

Abstract

A device for manufacturing artificial turf yarn is provided. In one embodiment, the device may include: a first-liquid supply pipe through which molten first liquid is supplied; a second-liquid supply pipe arranged in a space physically separate from the first-liquid supply pipe and through which molten second liquid is supplied; and a junction portion in which the first liquid introduced through the first-liquid supply pipe and the second liquid introduced through the second-liquid supply pipe join.

Description

{APPARATUS FOR MANUFACTURING YARN FOR ARTIFICIAL TURF}

The present invention relates to a device for manufacturing yarn for artificial turf.

The artificial grass system is composed of an artificial grass pad, a shock absorbing pad that supports the artificial grass pad, and a filler material laid on the artificial grass pad to achieve the effect of natural grass.

Since artificial grass was first developed in the United States to complement the various shortcomings of natural grass, it has been mainly used in sports fields for ball games such as baseball fields, soccer fields, and golf courses.

Artificial grass is increasingly being used because it always maintains a green color regardless of the season and is not restricted by environmental conditions such as climate, and because it is easy to construct and maintain.

Artificial grass has a higher initial construction cost than natural grass, but it is preferred because it can be used semi-permanently, is easy to maintain, and can always be maintained as an even surface suitable for exercise.

Artificial grass is artificially manufactured in the shape of grass using synthetic fiber materials. It is formed by stitching yarns formed in the shape of grass onto a base foam sheet, and in order to prevent the yarns formed in the shape of grass from separating from the foam sheet, a coating agent containing an adhesive component is applied to the lower surface of the foam sheet.

Recently, artificial grass has been researched and developed to have a similar feel to natural grass while being usable for a long period of time.

However, nylon was mainly used as the initial artificial grass yarn, and although yarn made of nylon is tough and wear-resistant, the surface friction of the yarn is high, so there is a risk of joint injuries or burns when rubbing against the body.

To overcome these problems, there have been attempts to modify the yarn composition, change the molding method, or develop a yarn manufacturing device, but it has been difficult to achieve properties and appearance similar to natural grass.

Specifically, conventionally developed artificial grass yarn manufacturing devices have difficulty in having facilities for manufacturing yarns having two or more characteristics in order to achieve similar properties and appearance to natural grass, or are designed with a structure that inevitably allows the manufactured yarns to exhibit two or more characteristics, or even if a structure is applied in which yarns are formed from two or more raw materials, the raw materials of two or more yarns are injected into spatially separated molds and then attached through separate pipes, resulting in a difficult structure in which the bonding of the two or more raw materials is insufficient.

The present invention is to solve the above problems and to manufacture a yarn manufacturing device for artificial grass having similar properties and appearance to natural grass, and to provide a yarn manufacturing device for artificial grass in which two or more raw materials are continuously manufactured into one yarn by using the fluid flow of the raw materials, and in which the bonding property of the two or more raw materials is improved.

In order to solve the above problems, the present invention provides an artificial turf yarn manufacturing device including: a 1-liquid supply pipe through which a molten 1-liquid is supplied; a 2-liquid supply pipe spatially separated from the 1-liquid supply pipe and through which a molten 2-liquid is supplied; and a junction portion where the 1-liquid introduced through the 1-liquid supply pipe and the 2-liquid introduced through the 2-liquid supply pipe join.

According to one embodiment of the present invention, process efficiency can be improved by allowing two or more raw materials to be continuously manufactured into one yarn by utilizing the fluid flow of the raw materials.

In addition, the present invention can improve the reliability of the quality of manufactured yarn by providing a joining portion at the upper part of the slit mold portion so that the hydraulic pressure and flow rate of the raw material are offset.

In addition, the present invention enables the production of yarn having properties and appearance similar to natural grass by allowing the first and second liquids to come into contact and be extruded in a slit mold section, thereby exhibiting natural curls and colors.

FIG. 1 illustrates a system for manufacturing artificial turf yarn according to one embodiment of the present invention.
FIGS. 2 to 5 illustrate a device for manufacturing artificial turf yarn. FIG. 3 illustrates the flow directions of liquid 1 and liquid 2 in FIG. 2, FIG. 4 illustrates in detail the form in which liquid 1 and liquid 2 merge, and FIG. 5 illustrates a cross-section along the xz axis at position AA in FIG. 4 to illustrate in detail the form in which liquid 1 and liquid 2 merge.
Figures 6 to 8 illustrate the shape of a slit mold portion according to each embodiment.

Hereinafter, embodiments of the present invention will be described in detail. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and the present embodiments are provided only to ensure that the disclosure of the present invention is complete and to more completely inform a person having ordinary skill in the art of the contents of the present invention.

Meanwhile, the yarn described in the present invention can be applied with a monofilament standard of 150 denier to 2500 denier.

Meanwhile, the monofilament referred to in the present invention may refer to a yarn, and for example, may refer to a yarn formed by contacting one liquid and two liquids.

The following is a detailed explanation with reference to the drawings.

The applicant of the present invention has made various design changes to the applicant's equipment and conducted various trials and errors in order to manufacture artificial turf yarn having two or more properties but similar properties and appearance to natural grass, thereby inventing the present invention. Specifically, the applicant of the present invention has caused raw materials, first and second solutions, which are physically separated and introduced through different paths, to merge at a junction, thereby canceling out hydraulic and flow rate differences, and then causing the first and second solutions to come into contact with each other and flow into a slit mold portion that performs extrusion molding of the yarn. Accordingly, the applicant of the present invention has developed an artificial turf yarn manufacturing device capable of manufacturing artificial turf yarn having similar properties and appearance to natural grass while achieving a continuous yarn formation process by allowing the first and second solutions to flow continuously.

FIG. 1 illustrates a system for manufacturing artificial turf yarn according to one embodiment of the present invention.

Referring to FIG. 1, a yarn manufacturing system for artificial turf may include a supply unit (10), a forming unit (20), and a shaping unit (30).

The supply unit (10) is for supplying a molten raw material to the forming unit, and a melted raw material of various known materials can be supplied.

For example, the raw material may include synthetic resins such as polypropylene, polyethylene, and nylon, as well as dyes for color expression, ultraviolet stabilizers, antioxidants, and antistatic agents for preventing static electricity generation.

For example, the original solution may include one or more of the above materials melted.

For example, the original solution may be supplied in two or more quantities, each of which may contain at least one different material.

The forming unit (20) is for forming artificial turf yarn from the raw material, and the artificial turf yarn manufacturing device (100) described below with reference to FIGS. 2 to 7 can be applied.

The forming section (30) is for forming the yarn formed in the forming section (20) according to the intended use, and may include elongation, cooling, and tufting of the yarn, and the order of each step, the applied device, and the manufacturing conditions may be changed according to the intended use.

FIGS. 2 to 5 illustrate a device for manufacturing artificial turf yarn. FIG. 3 illustrates the flow directions of liquid 1 and liquid 2 in FIG. 2, FIG. 4 illustrates in detail the form in which liquid 1 and liquid 2 merge, and FIG. 5 illustrates a cross-section along the xz axis at position AA in FIG. 4 to illustrate in detail the form in which liquid 1 and liquid 2 merge.

Referring to FIGS. 2 and 3, the raw material is supplied to the artificial turf yarn manufacturing device (100), and the artificial turf yarn is formed and then discharged to the molding unit (30) described above. In FIG. 3, the solid arrow indicates the flow of the first liquid (L1), and the dotted arrow indicates the flow of the second liquid (L2).

An artificial turf yarn manufacturing device (100) includes a 1-liquid supply pipe (1) through which molten 1-liquid is supplied, a 2-liquid supply pipe (2) spatially separated from the 1-liquid supply pipe (1) through which molten 2-liquid is supplied, and a junction (140) through which the 1-liquid supplied through the 1-liquid supply pipe (1) and the 2-liquid supplied through the 2-liquid supply pipe are joined.

At this time, liquid 1 and liquid 2 may be melted from the same material or from different materials. In addition, liquid 1 and liquid 2 may be melted from the same synthetic resin, but may contain different additives, such as dyes and antistatic agents, so as to exhibit different physical properties.

A first pressure control unit (110) may be provided at one end of the first liquid supply pipe (1).

The first pressure control unit (110) can control the hydraulic pressure of the first liquid flowing in through the first liquid supply pipe (1) according to preset conditions. Accordingly, the flowability is primarily controlled so that the two liquids joining at the joining unit (140) flow continuously at a uniform flow rate and hydraulic pressure, thereby improving the reliability of quality.

A first liquid discharge pipe (111) can be connected to the first pressure control unit (110).

The first liquid discharge pipe (111) can primarily flow the first liquid with controlled flowability, and for example, a height difference can be provided at both ends so that the weight of the first liquid can be added to the flow rate controlled by the first pressure control unit (110) to flow. For example, the first liquid discharge pipe (111) can be extended vertically.

A second pressure control unit (112) may be provided at one end of the first liquid discharge pipe (111).

The second pressure control unit (112) can control the hydraulic pressure of the first liquid according to preset conditions. Accordingly, the flowability is secondarily controlled so that the first liquid and the second liquid, which are joined at the joining unit (140), flow continuously at a uniform speed and pressure, thereby improving the reliability of quality. For example, the second liquid can flow by its own weight, and the first pressure control unit (110) and the second pressure control unit (112) can be applied to control the hydraulic pressure and the flow rate of the first liquid so as to correspond to the hydraulic pressure and the flow rate of the second liquid.

The second pressure control unit (112) can be connected to the first liquid chamber (120).

At one end of the first liquid chamber (120), a junction (140) is provided for the junction of the first liquid and the second liquid. At this time, the first liquid chamber (120) allows the first liquid passing through the first liquid chamber passage (121) penetrating the first liquid chamber (120) and the second liquid flowing in a spatially separated manner from the first liquid path to stably merge at the junction (140).

A slit mold part (150) is provided at the bottom of the joining part (140).

The slit mold part (150) is used to form the artificial grass yarn being manufactured into a preset shape, and an extrusion mold shape is applied.

The present invention is characterized in that the first and second liquids flow continuously while coming into contact with each other in the space defined by the slit mold part (150). That is, the first and second liquids flow continuously and are introduced into the slit mold part (150), and have a structure in which the yarn is formed in a form in which they come into contact with each other within the slit mold part (150). Accordingly, the bonding strength of the first and second liquids can be improved. In addition, since the first and second liquids can be formed in such a way that they come into contact with each other within the slit mold part (150), the present invention can easily control the contents of the first and second liquids constituting the yarn.

Meanwhile, the structure where liquid 1 and liquid 2 join is described in detail with reference to FIG. 4, and the joining portion (140) and the slit mold portion (150) are described in detail with reference to FIGS. 6 to 8.

A two-liquid chamber (130) may be provided at one end of the two-liquid supply pipe (2).

The two-liquid chamber (130) has a predetermined volume to store and/or pass through the two-liquid supplied through the two-liquid supply pipe (2) at a predetermined hydraulic pressure.

For example, the two-liquid chamber (130) may have a shape that gradually widens downward in a region connected to one end of the two-liquid supply pipe (2), for example, a tapered shape in which the cross-sectional area gradually widens downward, and may have a shape that gradually narrows downward again at a predetermined position, for example, a tapered shape in which the cross-sectional area gradually narrows downward.

For example, a hydraulic pressure gauge may be installed in the two-liquid chamber (130) to measure the hydraulic pressure of the two liquids.

A two-liquid chamber discharge pipe (131) can be connected to one end of the two-liquid chamber (130).

For example, the two liquids can flow by their own weight along the two liquid chamber discharge pipe (131).

A plurality of two-liquid separation discharge pipes (132) can be connected to one end of the two-liquid chamber discharge pipe (131).

The two-liquid separation discharge pipe (132) is provided to separate and discharge the two liquids into multiple confluences (140) before the two liquids flow into the confluence (140).

For example, the two-liquid separation discharge pipe (132) may have a structure formed as a single space in which a pipe extended at a predetermined angle and inclined is continuously formed at 360°. As an example, both the outer and inner sides of the two-liquid separation discharge pipe (132) may include a tapered shape so that the width of the xz-axis cross-section increases as it extends downward.

For example, a plurality of two-liquid separation discharge pipes (132) may be provided spatially separated.

A two-liquid merging pipe (133) can be connected to one end of the two-liquid separation discharge pipe (132).

The two-liquid confluence pipe (133) may refer to an area where the two liquids discharged from the two-liquid separation discharge pipe (132) flow through the lower part of the one-liquid chamber (120).

The two-liquid confluence pipe (133) may have a structure that extends horizontally by a predetermined length in a direction away from the two-liquid separation discharge pipe (132) so that the two liquids can move horizontally by a predetermined distance. Accordingly, the flow rate of the two liquids introduced by their own weight through the two-liquid separation discharge pipe (132) can be easily controlled.

One end of the two-liquid confluence pipe (133) is connected to a confluence part (140) provided on the upper part of the slit mold part (150).

The first and second liquids described above are introduced into the junction (140) so that they come into contact at the same height, and then continuously flow along the yarn forming tube (160) while coming into contact at the slit mold portion (150), thereby extruding and forming the yarn.

Referring to Fig. 4, liquid 1 and liquid 2 merge at the junction (140).

For example, liquid 1 and liquid 2 may come into contact at the junction (140). That is, the present invention is characterized in that yarn is continuously manufactured in a state in which liquid 1 and liquid 2 come into contact at the slit mold portion (150). However, if liquid 1 and liquid 2, which flow in from different directions, immediately join at the slit mold portion (150), it is not easy to control the continuously flowing liquid 1 and liquid 2 to have a uniform thickness within the slit mold portion (150). Therefore, the present invention provides a junction portion (140) at a location where continuously flowing liquid 1 and liquid 2 come into contact so that the hydraulic pressures of each fluid are offset, thereby maintaining the continuity of the process, thereby increasing process efficiency, improving the bonding strength of liquid 1 and liquid 2, and improving the reliability of the quality of the manufactured yarn.

For example, the junction (140) may have a structure that extends from the end of the 1-liquid chamber tube (121) in a direction away from the 2-liquid junction tube (133). By this structure, the phenomenon in which the 1-liquid, which has been introduced into the junction (140) by a pre-controlled pressure and its own weight, is pushed a predetermined distance by the hydraulic pressure of the 2-liquid, which has been introduced along the 2-liquid junction tube (133), can be reflected. Accordingly, by offsetting the hydraulic pressure and the flow rate difference between the 1-liquid and the 2-liquid at the upper part of the slit mold part (150), i.e., at the junction part (140), the 1-liquid and the 2-liquid can be stably introduced into the slit mold part (150) and extruded into a yarn.

Meanwhile, the present invention can produce artificial grass yarn with different sides and different sides in order to achieve similar properties and appearance to natural grass. For example, in an embodiment of the present invention, the content ratio of the first and second components constituting the yarn can be controlled.

For example, the hydraulic pressure of the first liquid and the hydraulic pressure of the second liquid flowing into the junction (140) can be controlled to be the same so that the first liquid and the second liquid can be extruded downward with equal thicknesses based on the center line of the slit mold portion (150).

For example, by controlling the hydraulic pressure of the first liquid flowing into the junction (140) to be higher than that of the second liquid, or by controlling the hydraulic pressure of the second liquid to be higher than that of the first liquid, it is possible to manufacture a yarn having properties and appearance similar to natural grass.

For example, to achieve a natural curl or color like natural grass, the first and second components may be made of any one selected from polypropylene, polyamide, polyethylene, nylon, polyvinyl chloride, polyurethane, and combinations thereof.

As a specific example, by applying the artificial turf yarn manufacturing device (100) of the present invention, yarn having a rough texture on one side and a soft texture on the other side can be manufactured.

As a specific example, by applying the artificial turf yarn manufacturing device (100) of the present invention, the first and second liquids having different thermal expansion characteristics can be applied so that the curl can change depending on the temperature conditions of the surrounding environment. In addition, since different colors are applied to the first and second liquids, the curl can change depending on the amount of sunlight, sunlight time zone, and temperature conditions of the surrounding environment, thereby manufacturing yarns having different colors. FIG. 5 shows the form in which the first and second liquids merge in the xz-axis cross-section at position AA of FIG. 4.

The merging portion (140) may include a 1-liquid merging portion (141) and a 2-liquid merging portion (142). The 1-liquid merging portion (141) refers to an area where the 1-liquid that has passed through the 1-liquid chamber passage (121) of FIG. 4 flows in, and the 2-liquid merging portion (142) refers to an area where the 2-liquid discharged from the lower end of the 2-liquid separation discharge pipe (132) flows in along the 2-liquid merging pipe (133) and then flows into the merging portion (140).

As shown in Fig. 5, a plurality of joining parts (140) and a plurality of slit mold parts (150) are provided, and each joining part (140) may be provided with a plurality of one-liquid joining parts (141) and two-liquid joining parts (142). Accordingly, a plurality of one-liquid chamber pipes (121) connected to a plurality of one-liquid joining parts (141) may be provided, and a plurality of two-liquid joining pipes (133) connected to a plurality of two-liquid joining parts (142) may be provided.

Figures 6 to 8 illustrate the shape of a slit mold portion according to one embodiment.

Referring to FIG. 6, the slit mold part (150) has a shape in which the thickness gradually increases from the two ends to the center, and may have, for example, a shape similar to a diamond.

For example, a slit mold part (150) may have a structure that is symmetrical with respect to the center line (M).

For example, the slit mold part (150) may be provided with a protrusion. The protrusion may provide a curve so that the artificial grass manufactured using the yarn of the present invention looks similar to natural grass leaves, or may perform the function of absorbing flying dust or moisture.

For example, the protrusions may be provided in multiple numbers. For example, the protrusions may have a first protrusion (151) formed in the center and second protrusions (152) formed on both sides thereof, each of which is smaller than the first protrusion (151). Accordingly, the verticality of the yarn may be improved.

Figure 7 shows the form in which liquid 1 and liquid 2 flow into the slit mold section of Figure 6.

The artificial turf yarn manufacturing device (100) of the present invention is characterized in that the first and second liquids are introduced while coming into contact with the slit mold part (150), and as shown in Fig. 7, it can be confirmed that the first and second liquids are introduced with equal thickness based on the center line (M) of the slit mold part (150).

Referring to Fig. 8, the slit mold portion (150a) may further include a protrusion (153). The protrusion (153) may be formed only on the first protrusion (151) provided in the central portion, may be formed only on the second protrusion (152), or may be formed on both the first protrusion (151) and the second protrusion (152).

In addition, smaller protrusions may be formed on the protrusion (153). Accordingly, the verticality of the yarn can be improved.

As described above, the specific description of the present invention has been made by means of embodiments with reference to the attached drawings. However, the above-described embodiments have only been described as preferred examples of the present invention, and therefore, the present invention should not be understood as being limited to the above-described embodiments, and the scope of the rights of the present invention should be understood by the claims described below and their equivalent concepts.

For example, the drawing is a schematic representation of each component as a subject to help understanding, and the thickness, length, number, etc. of each component depicted may differ from the actual one as the drawing is being created. In addition, the material, shape, dimensions, etc. of each component shown in the above embodiment are only examples and are not particularly limited, and various changes may be made within a range that does not substantially deviate from the effects of the present invention.

10: Supply Department
20: Formation
30: Plastic surgery
1: 1 liquid supply pipe
2: 2-liquid supply pipe
100: Artificial grass yarn manufacturing device
110: 1st pressure control unit
111: 1 liquid discharge pipe
112: Second pressure control unit
120: 1 liquid chamber
121: 1 liquid chamber clearance
130: 2-fluid chamber
131: 2-liquid chamber discharge pipe
132: Two-liquid separation discharge pipe
133: Two-liquid confluence
140: Joining part
141: 1 liquid conjugate
142: Two-liquid confluence
150, 150a: Slit mold part
151: First projection
152: Second protrusion
153: bump
160: Yarn forming tube
M: Center line
L1: 1 liquid
L2: 2 liquids

Claims (5)

In a device for manufacturing artificial grass yarn with different sides,
A liquid supply pipe through which molten liquid is supplied;
A second liquid supply pipe, which is placed in a space physically separated from the first liquid supply pipe and through which molten second liquid is supplied;
A junction where the first liquid introduced through the first liquid supply pipe and the second liquid introduced through the second liquid supply pipe join;
A slit mold part arranged below the above joining part;
A two-liquid separation discharge pipe for separating and discharging the two liquids supplied through the two-liquid supply pipe into a plurality of the above-mentioned junctions before the two liquids flow into the above-mentioned junction;
A two-liquid confluence pipe extended to a predetermined length so that the two liquids separated through the two-liquid separation discharge pipe can flow horizontally; and
A 1-liquid chamber having a 1-liquid chamber passage through which the 1-liquid passes through the upper portion of the above-mentioned junction;
Including,
The above liquid 1 and liquid 2 flow continuously into the slit mold section, and the yarn is formed in a form where they come into contact with each other within the slit mold section.
The above two-liquid confluence pipe extends from the lower portion of the above one-liquid chamber, and the end of the above two-liquid confluence pipe is connected to the above junction portion.
Since the above-mentioned junction portion has a structure extending from the end of the above-mentioned 1-liquid chamber tube in a direction away from the above-mentioned 2-liquid junction pipe, the above-mentioned 1-liquid, which has been introduced into the above-mentioned junction portion by a pre-controlled pressure and dead weight, is pushed a predetermined distance by the hydraulic pressure of the above-mentioned 2-liquid, which has been introduced along the above-mentioned 2-liquid junction pipe, thereby canceling out the hydraulic pressure and the flow rate difference between the above-mentioned 1-liquid and the above-mentioned 2-liquid at the upper portion of the slit mold portion, thereby allowing the above-mentioned 1-liquid and the above-mentioned 2-liquid to stably introduce into the slit mold portion.
The above artificial grass yarn is of 150 denier to 2500 denier based on monofilament, and the device for manufacturing artificial grass yarn. delete delete delete delete