KR20100110166A - The product method, coating thread, product method of textile and textile taken air pocket - Google Patents

Abstract

PURPOSE: It coats to the state giving the tension the air pocket mechanical stretched yarn. Using the force of restitution created in the air pocket mechanical stretched yarn. The cloth of the natural texture can be produced. CONSTITUTION: The solitary person shaft coating corp manufacturing method having air pocket. The step of positioning in the coating system the air pocket fiber yarn(10). In the state giving the fixed tension to the air pocket fiber yarn. The step supplied to the yarn coating apparatus. The Polymer melt solution is in thrown by the case of the yarn coating apparatus.

Description

Manufacturing method of high stretch coating yarn with air pocket, high stretch coating yarn, manufacturing method of high stretch fabric with air pocket and high stretching fabric {The product method, coating thread, product method of textile and textile taken air pocket}

The present invention is applied to the high tension yarns with air pockets in a tensioned state, and utilizing the natural texture generated by the coating layer is crushed by the restoring force generated in the air pockets stretched yarns; Furthermore, weaving the coated yarn in a tensioned state allows the air pocket to produce a more natural textured fabric through chaos, such as the irregular and natural weft, the overlapping and warping of the warp, due to the restoring force generated from the stretch yarn. It relates to a high stretch coating yarn with, a high stretch fabric woven with this high stretch coating yarn, and a manufacturing method for producing them.

In general, the high-stretch air pocket fiber yarn 10 is formed by overlapping a plurality of fibers to form a single fiber yarn, but at a certain interval in the middle to have a tangle (1d) area to be knotted like a knot can be naturally filled with air The fiber yarn 10 provided with the pocket 1c part is called. This air pocket fiber yarn (see FIG. 2) is not straight, like the typical fiber yarn of FIG. 1 shown. That is, a general fiber yarn is a fiber that is pulled out in a state where many or one fiber is twisted or overlapped. By the way, the air pocket high stretch fiber yarn 10 used in the present invention has a plurality of fibers overlapping, as shown in Figure 2 shown at regular intervals, has a tangle (1d) of the aggregated portion. Of course, when the tangle 1d is formed, the left and right sides of the pocket 1c are naturally inflated. The air pocket fiber yarn 10 has a space in which air penetrates into this pocket 1c part, and is utilized as a fiber with high effect of heat retention and moisture retention.

Of course, such air pocket fiber yarn is a special yarn having a function that is widely used as a known fiber. However, there is no intention to produce a separate fabric by coating specifically using such a fiber yarn, development is insignificant.

The present invention is applied to the high tension yarns with air pockets in a tensioned state, and utilizing the natural texture generated by the coating layer is crushed by the restoring force generated in the air pockets stretched yarns; Furthermore, weaving the coated yarn in a tensioned state allows the air pocket to produce a more natural textured fabric through chaos, such as the irregular and natural weft, the overlapping and warping of the warp, due to the restoring force generated from the stretch yarn. It relates to a high stretch coating yarn with, a high stretch fabric woven with this high stretch coating yarn, and a manufacturing method for producing them.

Method for manufacturing a high-strength coated yarn with air pocket of the present invention, the coating yarn manufacturing method, the first step: tow the air pocket fiber yarn (10) to position in the coating system; Second step: supplying a yarn coating device in a state in which a constant tension is applied to the air pocket fiber yarn (10); The third step: coating the polymer melt into the case 31 of the yarn coating device to a predetermined thickness on the outer peripheral surface of the air pocket fiber yarn (10); The fourth step is characterized in that it comprises a step of producing a high stretch coating yarn by curing the coating yarn 12 that achieved the coating.

Here, the constant tension of the second step is preferably a tension that is not stretched by its weight when the air pocket fiber yarn 10 is hooked on the yarn coating device.

The yarn coating apparatus includes an extrusion mechanism for extruding and applying a polymer melt to an outer circumferential surface of an air pocket fiber yarn 10 in which a plurality is independently and continuously supplied, and the polymer applied to the air pocket fiber yarn 10. It is provided with a cooling mechanism for solidifying the melt, the extrusion mechanism, the passage (61) through which the extruded polymer melt flows, and the macro passage so that the polymer melt can flow out toward the air pocket fiber yarn 10 ( A block (60) provided with a plurality of proprietary passages (62) formed independently from (61); Each air pocket by connecting the large flow passage 61 to each of the small flow passages 62 and distributing and extruding the polymer melt flowing through the large flow passage 61 in the same amount to each of the small flow passages 62. It may be configured to include a dispensing unit 70 to independently apply the polymer melt to the outer peripheral surface of the fiber yarn (10).

At this time, the yarn coating device, the case 31 for forming a nozzle assembly for supplying the polymer melt under the same pressure to the small flow path 62 formed in the block 60 through the rotational force of the motor 74; A multitone block 800 fastened by a bolt 801 to the upper portion of the case 31 and having a tournament distribution channel 817 through which a multitone polymer melt is moved; The multitone polymer melt injector 900 for injecting a polymer melt extruded into the multitone polymer melt supply port 802 formed on one side of the multitone block 800 may be further included.

On the other hand, high elastic coating yarn having an air pocket according to the present invention, the air pocket fiber yarn 10 is buried in a state having a constant tension inside the coating yarn; It comprises a polymer melt layer (1k) coated with a predetermined thickness on the outer peripheral surface of the air pocket fiber yarn 10, the polymer melt layer by the elasticity of the air pocket fiber yarn 10 buried with the predetermined tension (1k) is characterized in that it is formed to have an irregular twisted form by causing the contraction.

In addition, the method of manufacturing a high-stretch fabric having an air pocket according to the present invention, using the air pocket coating yarn 12 coated with a polymer melt layer (1k) to a predetermined thickness on the outer peripheral surface of the air pocket fiber yarn (10) Weaving the weft and warp of the fabric with a loom, it is characterized in that the weave in a pulled state by giving a constant tension to the air pocket fiber yarn (10).

Here, the constant tension is preferably a force such that the polymer melt layer 1k coated on its outer circumferential surface is irregularly twisted by the elasticity of the air pocket fiber yarn 10.

In addition, in the method of manufacturing a high-stretch fabric having an air pocket according to the present invention, after finishing the weaving of the stretch fabric, the process of fixing the shape of the fabric by releasing the tension given the force and heating and cooling with heat of 120-180 ° Can be given.

On the other hand, a high-stretch fabric having an air pocket according to the present invention, the polymer is coated with a constant thickness on the air pocket fiber yarn 10 and the air pocket fiber yarn 10 outer peripheral surface buried in a state having a constant tension therein The air pocket coating yarn 12 made of a melt layer 1k is used as the weft and warp yarns of the stretch fabric and is woven horizontally and vertically, and by the stretching action of the air pocket fiber yarn 10 buried in the constant tension state. The polymer melt layer (1k) is characterized in that the air pocket coating yarn 12 is formed so as to have an irregular twisted shape and overlapping horizontally and vertically.

According to the present invention has the advantage of being able to produce a coating yarn having a very specific elasticity, and the effect of keeping warm and moisturizing high.

According to the present invention, by using the air pocket fiber yarn, which is a special fiber, there is an advantage of removing the odor of the synthetic resin that may be generated in the composition to be applied, and improving the effects of warming and moisturizing.

According to the present invention is more natural, there is an advantage that can create a woven fabric of the stomach, inclined to feel the sense of Hanji.

The present invention relates to a method for producing a high stretch coating yarn. Therefore, the configuration of the present invention and its operation will be described in detail with reference to FIGS. 2 to 14. That is, the present invention is largely divided into four categories, one is a method of manufacturing a high stretch coating yarn having an air pocket and the other is a high stretch coating yarn manufactured through the manufacturing method of a high stretch yarn having the air pocket, and the other One is a fabric manufacturing method of weaving a high stretch fabric using a high stretch coating yarn having an air pocket, the other is a high stretch fabric produced by this manufacturing method. Therefore, this invention is demonstrated in this order.

[Coating company manufacturing method]

The present invention is the first step: a plurality of high-stretch air pocket fibers (10) through the step of placing them in the coating system, the second step: a state given a constant tension to the high stretch air pocket fibers (10) After the step of supplying to the yarn coating device, the third step: the polymer coating into the case 31 of the yarn coating device is subjected to the coating step. And the fourth step: to harden the coating yarn 12 that achieved the coating to produce a high stretch coating yarn.

That is, the present invention forms a plurality of air pocket fiber yarn (notice) 10 already produced in the form of a roll or a bundle is placed in the coating system. The coating system of the present invention is a system equipped with a plurality of machines for coating the outer peripheral surface of the air pocket fiber yarn (10). Some of these machines are already known and have been realized through the applicant of the present invention. All known parts and developed contents are combined with the manufacturing method of the present invention to produce a new type of high-stretch air pocket coating yarn 12. To this end, in the present invention, the first step is to prepare a plurality of air pocket fiber yarns 10 in front of the coating system to start the coating.

Next, the present invention is subjected to a second step: supplying the yarn coating device in a state in which a predetermined tension is given to the high-stretch air pocket fiber yarn (10). In other words, the high-stretch air pocket fiber yarns are continuously supplied at the same speed in a pulled state without tensioning as in the conventional method. The yarn coating apparatus described in the present invention consists of two. One is registration No. 20-383281 (raw coating device) developed by the applicant of the present invention and registered on April 25, 2005, and is a "raw color coating device" recently developed by the present applicant. In the present invention, the registered declaration is referred to as yarn coating device 1 (100), and the "developed color coating device" developed later will be described as yarn coating device 2. Details will be described later, but the coating is applied in a pulled state through the yarn coating device 1, 2. Of course, the reason is that the air pocket high stretch fiber yarn 10 of the present invention is too stretchy compared to natural yarns and general synthetic fiber yarns stretched when given a little force, whistle and give a tension to swing around The coating is pulled. In addition, the more important purpose is to produce a coating yarn 12 in such a state that the tension is pulled, the air pocket fiber yarn 10 later the restoring force is generated and shrinkage action, the outer peripheral surface is wrapped This is because the coating layer (polymer melt layer; 1k) is distorted in an irregular shape and direction, resulting in a new coating yarn 12 that gives a natural texture and feel not found in conventional coating fibers.

And the third step of the present invention: the polymer melt is subjected to the step of coating the coating to the case 31 of the yarn coating apparatus, the polymer melt is a composition for coating in order to utilize the functionality of the coating yarn of the present invention, In some cases, the composition may be added with a special function such as a flame retardant composition or other non-combustible composition, or may be coated with a general synthetic resin. In the present invention, the coating is achieved by using the polymer melt while simultaneously passing through the yarn coating device 1 or 1 and 2. Using only the above-mentioned yarn coating device 1, but only a single color coating, if both yarn coating devices 1, 2 are used, it is possible to produce a coating yarn 12 having a coating yarn and multi-tone of various cross-sectional shapes.

Next, the present invention is to prepare a high stretch coating yarn by curing the coating yarn 12 that achieved the fourth step: coating. That is, the polymer melt in the molten solution state is coated on the outer circumferential surface of the high stretch air pocket fiber yarn 10, and cured to complete the coating yarn. There are two types of curing methods: water-cooled and air-cooled. Water-cooled is a method of passing through a bath containing cooling water and spraying using a nozzle, and air-cooling is a method of cooling in air. As a result, the coating yarn 12 of the present invention is reborn as a perfect coating yarn 12 through this cooling method.

If so, that is to say, the tension in the second step is described in detail how much tension. This constant tension is most preferably such that the tension is not stretched by its own weight when the high stretching air pocket fiber yarn 10 to the yarn coating device. The reason why it is difficult to clearly define this in the present invention is because the characteristics of the high-stretch air pocket fiber yarn 10 is differentiated. In fact, the high-strength air pocket fiber yarn 10 has a difference in the degree of expansion according to the manufacturer and the working environment at the time of manufacture. In addition, the tension of the tension varies depending on the state in which the producer intends to produce the degree of expansion of the coating yarn. In other words, in the case of air pocket fiber yarns, which are highly stretchable among the air pocket fiber yarns, the air pockets are highly liable to be stretched when the yarn coating device of the present invention is pulled to a higher tension and thus the coating operation is performed. It is possible to prevent the fiber yarn from being oriented toward one side of the coating layer (= polymer melt layer; 1k). In addition, when the operator completes the coating of the air pocket fiber yarns and reduces the length by the restoring force of the air pocket fiber yarns 10, the coating layer surrounding the outer peripheral surface is also crushed or bent, and the subsequent processing According to the characteristics of the fabric or article to be finished through, there is a desired level of bending and crushing. Fabrics or products that want a natural bend and crush very much should be pulled to a very high tension to remain taut; otherwise they should be pulled to a lesser tension.

In general, the applicant of the present invention used a method of applying a friction to the outer circumferential surface of the air pocket fiber yarn in the manner of maintaining the tension of the air pocket fiber yarn of the present invention to impart the tension to the magnitude of the friction force. Therefore, in particular in the present invention, it is difficult to numerically limit the size of the tension, but the degree to which the coating is smoothly carried out by being put into the yarn coating apparatus of the present invention, which is not stretched by the weight of the air pocket fiber itself. Tension, which is the tension at which the fiber does not swing back and forth by a slight force or wind.

More specifically, the tension of the air pocket fiber yarn 10 itself mentioned in the present invention is not stretched by the weight should be utilized by the present invention for the following reasons. First, the present invention is to coat the air pocket fiber yarn 10 having a high elasticity, the air pocket fiber yarn has a feature of high elasticity to maintain a constant and continuous tension to perform the coating operation.

Second, the above-mentioned tension is the most suitable tension when the high-stretch air pocket fiber yarn to the yarn coating device 1, 2 which is part of the coating system of the present invention. As a result, the tension that is not stretched by the weight of the air pocket fiber itself mentioned in the present invention is the optimum tension when combined with both the properties of the high-stretch air pocket fiber yarn and the yarn coating devices 1 and 2.

Then the yarn coating apparatus which is part of the coating system of the present invention will be described in detail. Although already briefly described, the coating system of the present invention may be coated in two forms. One is a method of manufacturing a coated yarn by coating the polymer melt using only yarn coating apparatus 1, and the other is a method of manufacturing a multitone coated yarn by coating the polymer melt in combination with yarn coating apparatuses 1 and 2. The former may produce a monochromatic coated yarn, but the latter may produce a multitone coated yarn.

Therefore, based on this order, first, a method of coating polymer melt using only yarn coating device 1 will be described, and a method of coating polymer melt with multitone by combining yarn coating devices 1 and 2 will be described.

First, the yarn coating apparatus 1 extrudes a polymer melt to the outer circumferential surface of the air pocket 1c fiber yarn 10 continuously supplied in one direction, as shown in FIGS. 3 to 6, and then applies the yarn coating device to the outer circumferential surface of the air pocket fiber yarn 10. In the yarn coating device having an extrusion mechanism and a cooling mechanism for solidifying the polymer melt applied to the air pocket fiber yarns 10 by the extrusion mechanism, the air pocket fiber yarns 10 are independent of each other A plurality are supplied; The extrusion mechanism has a large flow passage 61 through which the extruded polymer melt flows, and a plurality of oil flow passages formed independently of the large flow passage 61 and the polymer melt flows out toward the air pocket fiber yarn 10. Block 60 with 62; And connecting the passages 61 to the respective passages 62 so that the polymer melt is applied to the outer circumferential surface of each of the air pocket fiber yarns 10 independently from each other, and flowing through the passages 61. And a dispensing unit 70 for dispensing the polymer melt in the same amount into each of the small oil passages 62.

That is, the action is that each of the high-stretch air pocket fiber yarns 10, which are four (up to 12) yarns, as shown in Figures 3 to 6 shown in each of the extension member 36 and each insertion member The through hole 361 and 331 of the 33, the yarn insertion hole 332 of the insertion member 33, and the nozzle hole 341 so as to penetrate the center of the nozzle hole 341 of each nozzle 34 ) To accommodate. In this state, when the yarn coating device 1 (100) is driven such that each air pocket fiber yarn 10 is supplied at a constant speed, each air pocket fiber yarn 10 is moved in one direction independently of each other at a constant speed and The polymer melt of the present invention supplied from the extruded portion 5 is extruded into the main passage 61 of the block 60. In addition, since the inflow spaces 731 connected to the main passage 61 of the block 60 are formed in the housing 73 of the distribution unit 70, the polymer melt is supplied to the inflow spaces 731. As such, the composition melts supplied to the respective inflow spaces 731 of the housing 73 are extruded into the individual passages 62 of the block 60 as the motor 74 of the distribution unit 70 is operated. Is as follows. As the motor 74 of the dispensing unit 70 rotates clockwise, for example, as indicated by the arrow in FIG. 6, and the main gear 71 connected to the motor 74 also rotates clockwise, the main gear 71 Each of the satellite gears 72 geared to the rotation is rotated in a counterclockwise direction, and as the respective satellite gears 72 rotate, the polymer melt supplied to each inflow space 731 is each satellite gear 72. Between the teeth and teeth and contained in the discharge space 733 formed by the inner wall of the housing 73 is rotated counterclockwise to be extruded into each outlet space 732 of the housing 73. Since each outlet space 732 of the housing 73 is connected to each of the passages 62 of the block 60, the polymer melt supplied to each outlet space 732 is each of the passages of the block 60 ( 62). In this way, the polymer melts supplied to each of the small passages 62 of the block 60 include the respective through-holes 311 of the case 31 and the respective insertion members 33 of each of the small passages 62 of the block 60. Each through hole is connected to the nozzle hole 341 of each nozzle 34 through the gap between the connecting hole 321 and the conical end of the insertion member 33 and the fitting member 32 and the nozzle 34. Extruded through the hole 311, the connection hole 321 and the gap 34 to the nozzle hole 341 of each nozzle 34, the polymer melt is extruded from the outer peripheral surface of each air pocket fiber yarn (10) To be applied. At this time, since each air pocket fiber yarn 10 is continuously supplied in one direction, the polymer melt is applied to the outer circumferential surface of each air pocket fiber yarn 10. At this time, since each air pocket fiber yarn 10 is continuously supplied in one direction, the polymer melt is continuously applied to the outer circumferential surface of each air pocket fiber yarn 10 and the air pocket fiber yarn 10 continues to move in one direction. Done. Thereafter, the air pocket fiber yarn 10 coated with the polymer melt is solidified via the cooling mechanism 40 using water cooling or the like, and is wound up by a winder or a pulling means (not shown).

When using the yarn coating device 1 (100) of the present embodiment as described above, since it is possible to apply the polymer melt to the four air pocket fiber yarns 10 at the same time, it is possible to greatly increase the coating productivity, Accordingly, it is possible to reduce the coating production cost of the air pocket fiber yarn (10).

In addition, when the main gear 71 and the satellite gear 72 of the distribution unit 70 is rotated at a constant speed, it is possible to continue to supply the same amount of the polymer melt supplied to each of the small passage 62 of the block 60, It is possible to obtain a coating yarn of the same quality as the coating state of each air pocket fiber yarn (10). That is, the coating thickness of each of the air pocket fiber yarns 10 is the same, and the coating state of each air pocket fiber yarn 10 is also uniform in the longitudinal direction of the air pocket fiber yarn 10. If the diameter of the nozzle hole 341 of each nozzle 34 is changed, the thickness of a coating yarn can be adjusted.

On the other hand, in the present embodiment, four air pocket fibers 10 are supplied so that the polymer melt is coated on the outer circumferential surface of each of the air pocket fibers 10, but 6 air pocket fibers 10 Independently supplying each other and providing six satellite gears 72 of the distribution unit 70 may be configured to coat the six air pocket fiber yarns 10 independently of each other. Of course, 12 air pocket fiber yarn coatings are also available.

Next, a method of coating a multi-tone polymer melt through a yarn coating apparatus of a combination of yarn coating apparatuses 1 and 2 of the present invention will be described. That is, this is a device in which the yarn coating device 2 is combined or combined with the yarn coating device 1 described above. This yarn coating device 2 slightly deforms the case used in the yarn coating device 1, and is coupled to the yarn coating device 1 with a slight deformation applied to the nozzle portion therein. The structural aspect thereof will be described with reference to FIGS. 7 to 14.

In particular, as shown in Figures 7 and 14, the yarn coating device 2 of the present invention, the nozzle is supplied to the polymer melt under the same pressure to the small flow path 62 formed in the block 60 through the rotational force of the motor 74 A case 31 forming an assembly; The multi-tone block is fastened to the case 31 and the bolt 801 in the form of a block 60 to the upper portion of the case 31, and formed a tournament distribution channel 817 through which the multi-tone polymer melt is moved ( 800); A multitone polymer melt injector 900 for injecting a polymer melt extruded into a multitone polymer melt supply port 802 formed at one side of the multitone block 800; Yarn coating device 2 made; It is configured to include more. In order to be smoothly combined with the yarn coating device 1, a slight shape change is applied to the case and the nozzle and the nozzle support inside.

More specifically, the bolt 801 is fastened to the nozzle assembly case 31 (slightly changed in shape) of the yarn coating apparatus 1 of the pre-registration right, the multitone block 800 having the same size or similar to that of the case 31. The multi-tone block 800 also has the same flow path 817 as the number of nozzles 820 formed in the case 31 to supply the multi-tone polymer melt to the upper portion of the case 31. The side of the multi-tone block 800 of the present invention is provided with a supply port 802 of the polymer melt, which is in communication with the supply port 802 is a multi-tone polymer melt injector 900. The multitone polymer melt injector 900 is supplied from the bottom to the outer peripheral surface of the air pocket fiber yarn 10 while injecting the multitone polymer melt into the supply port 802 of the multitone block 800 through a controllable pressure. When the coated yarn 12 is produced by simultaneously supplying the polymer melt with different polymer melts, the coated yarn 12 of various colors can be produced around the air pocket fiber yarn 10. will be.

Then, the detailed configuration and the action according to the nozzle assembly as follows. 7, 8, and 14, there is a case 31 having a plurality of through holes 311a penetrating through the inside and having a stepped portion and a fastening portion 899 formed thereon, and the fastening portion 899. A nozzle hole 821 is formed on an inner circumferential surface thereof, and there is a nozzle 820 inserted into the wedge-shaped through space portion 822, and the case 31 is fastened from the front surface of the nozzle 820. There is a fixing member 830 fastened to the portion 899 to stably fasten the nozzle 820. In addition, the case 31 is inserted into the through hole 311a, but the communication hole 841 is formed therein, and the stop step 842 is formed at one side of the outer circumferential surface at a predetermined interval from the nozzle 820. There is a nozzle support 840 to be inserted and inserted, inserted into the front portion of the nozzle support 840 and a through hole 851 is formed therein in the form of a ballpoint pen, the wedge-shaped through space of the nozzle 820 at the time of fastening There is a primary nozzle 850 is fastened to form a predetermined interval in the portion 822, while pressing the stop step portion 842 through a screw 861 on the back of the nozzle support 840 case ( 31 is a cylindrical pressure port 860 to be fastened. Accordingly, the combined polymer melts supplied through the small passage 62 of the block 60 and the multitone polymer melts supplied through the multitone block 800 are connected to the outer circumferential surface of the primary nozzle 850 and the nozzle 820. Coexisting by a predetermined amount between the inner through space portion 822 of the yarn to form a coating layer of various tones on the outside of the air pocket fiber yarn (10).

Here, the nozzle assembly is a type of block 60 in which the air pocket fiber yarn 10 is incident, and this can be the coated yarn 12, and eight or twelve coated yarns (4 or 6 further expanded at the same time) 12) is a block assembly that can be manufactured.

7 and 8 illustrate this form in detail. First, the case 31 is formed with a plurality of through holes 311a through which the nozzle 820 and the nozzle support 840 are fitted. The nozzle 820, the nozzle support 840, the primary nozzle 850, and the like are fitted to the 311a). Of course, the bottom of the case 31 has a block 60 in which a separate channel 62 is formed so that the polymer melt can be supplied through the channel 62. And the peculiar point is that the nozzle 820 and the primary nozzle 850 is provided in the rear of the fixing member 830 in the through hole 311a, and forms a through space portion 822 spaced therebetween. Is there. This through-space portion 822 is a space to be coated with the air pocket fiber yarn 10 in a multi-tone of various colors. Of course, in order to make this possible, the nozzle support 840 is formed with a main polymer melt injection groove 844 formed by turning one side of its outer peripheral surface, and the front length of the nozzle support 840 in the injection groove 844. A communication hole 845 communicating with the injection groove 844 in a direction, and a multi-tone polymer melt injection groove 846 is formed on one side of another outer circumferential surface, and the nozzle support 840 in the injection groove 846. The multi-tone communication hole 847 communicated with the injection groove 846 in the longitudinal direction of the front side) is formed to allow the multi-tone polymer melt of various colors to coexist.

Then, the air pocket fiber yarn in the present invention will be described in sequence the coating process is put into the yarn coating device (combination of yarn coating devices 1 and 2) of the present invention. The air pocket fiber yarn 10 passes through the yarn coating device (combination machine of 1 and 2), the communication hole 841 formed in the nozzle support 840 which is a part of the nozzle assembly, as shown in Figs. It exits the through hole 851 of the primary nozzle 850 in front of it and exits to the nozzle hole 821 in front of it so that it can be towed through a separate towing means (not shown). By the way, the communication hole 841 formed in the nozzle support 840 has a large diameter, as shown in the drawing, and the through hole 851 formed in the primary nozzle 850 in front of the nozzle support 840 has a small diameter. The air pocket fiber yarn 10 is enough to pass through. The size of the nozzle hole 821 formed in the nozzle 820 is larger than that of the through hole 851 formed in the primary nozzle 850. The reason is that the polymer melt is injected into the outer circumferential surface of the primary nozzle 850, and the multi-tone polymer melt supplied from the upper multitone block 800 is also injected into the primary circumferential surface of the primary nozzle 850. Filled in the through-space portion 822 between the nozzle 850 and the nozzle 820, the filled multi-tone polymer melt and polymer melt is coated on the outer peripheral surface of the air pocket fiber yarn 10 coated yarn 12 If it becomes constant, its thickness will increase and it will have a larger diameter to match its diameter. The polymer melt and the multi-tone polymer melt described in the present invention are not different from each other, and are introduced in different colors to be described differently for their distinction, and do not make a big difference in particular physical properties.

Then, the process of injecting the polymer melt and the multi-tone polymer melt into the through space 822 will be described sequentially. In the case of the polymer melt, as shown in the applicant's registration declaration, the polymer melt rises in the small passage 62 of the block 60 and enters the through hole 311a of the case 31 through the power of the motor 74. Done. Then, the inside of the through hole (311a) is provided with a nozzle support (840), the polymer melt injection groove (844) of digging the outer peripheral surface of the nozzle support (840) directly in the possession of the block 60 As such, the polymer melt enters the injection groove 844. Of course, the injection groove 844 is rounded and circumscribed on the outer circumferential surface of the nozzle support 840, and exits into the communication hole 845 penetrated laterally in the state filled in the injection groove 844. 7, 8, and 14, the communication hole 845 passes through the injection groove 844, in the horizontal direction toward the front of the nozzle support 840, that is, in the longitudinal direction of the nozzle support 840 It is penetrated. Therefore, the through hole faces the through space 822 existing between the primary nozzle 850 and the nozzle 820 so that the polymer melt immediately fills the through space 822. In this case, however, an important point in the embodiment of the yarn coating apparatus (combined embodiment of 1 and 2) is that the multi-tone polymer melt is introduced in the same way in the flow path 817 of the upper multi-tone block 800. That is, an injection groove 846 is formed on the outer circumferential surface of the nozzle support 840 but smaller than the injection injection groove 844 of the polymer melt described above, into which a separate multitone polymer melt may be injected. In the case of the injection groove 846, a communication hole 847 penetrating in the longitudinal direction of the nozzle support 840 is formed. 7, 8, and 14, the positions of the injection grooves 844 and 846 and the communication holes 845 and 847 and the formation structure thereof are shown in detail. The polymer melt injection grooves 844 are large and communication holes. Although a plurality of 845 is formed, the injection groove 846 of the multitone polymer melt is small and one communication hole 847 is formed. Therefore, in the coating of the air pocket fiber yarn 10, the worker supplies the polymer melt of the main coating color through the block 60 at the bottom, and the tone of the color to give a different pattern or color to the polymer melt. The multi-tone polymer melt having the above is supplied through the flow path 62 of the multi-tone block 60 at the top.

Of course, the present invention shows only the state in which the multi-tone polymer melt injection groove 846 and the communication hole 847 is formed, but is not limited thereto. Two or three or more horizontal communication holes 847 passing through the injection groove 846 in a state in which the injection groove 846 is further extended to be excavated in a predetermined length on the outer circumferential surface of the nozzle support 840. If formed, the color of the multi-tone polymer melt is coated on one air pocket fiber yarn 10 can be formed in a wide variety.

In fact, in the coating apparatus of the pre-registered design of the present invention, a method of accurately injecting the polymer melt at the same pressure into the plurality of nozzles 820 formed in one block 60 has been proposed. However, in the present invention, when the multitone polymer melt is introduced into the multitone block 800, there is a difference in the manner of supplying the multitone polymer melt at the same pressure. In other words, in the present invention, the polymer melt is introduced by a supply method composed of a planetary gear 72, but the multi-tone block 800 of the present invention forms a tournament-type flow path in forming the flow path 817. Supplying a multi-tone polymer melt under the same pressure conditions.

7, 8, 12, and 14, the multi-tone block 800, 2-12 tournament-type flow path 817 can be selectively applied to correspond to the number of nozzle assemblies inserted therein. . Herein, the tournament-type flow path capable of applying the same pressure is a flow path 817 in which the flow path 817 is formed in the inside of the block, that is, through the supply port 802 into which the multi-tone polymer melt is introduced. By precisely combining the distance and the diameter), the pressure from the ends of all the flow paths 817 is maintained to be the same so that the same amount of the multi-tone polymer melt can be ejected for the same time. 12 illustrates an embodiment of a tournament-type flow path formed inside the multi-tone block 800 of the present invention. In the case of (a), the first flow path 817 starts, and the flow path In a state where the 817 is divided into two, the second channel is further divided into two to form four flow paths 817 to form a flow path 817 in which four nozzles 820 may be formed in the multi-tone block 800. The way is shown. In the case of (b), four flow paths 817 are formed by splitting into two flow paths 817 at the beginning of the first supply port 802 and then splitting into two flow paths 817. In the state in which two of the 817 are separated from each other, each of the three flow paths 817 is separated from the two flow paths 817, and thus six flow paths 817 are formed. Of course, in the case of (C) and (D), the flow paths 817 are formed in the same manner, and eight and twelve flow paths 817 are formed. The most important feature of the present invention is that the flow path 817 is formed by uniformly matching the diameter and distance of the flow path 817 in order to maintain the same pressure in forming the flow path 817. Therefore, the same pressure may be applied to each of the divided flow paths 817 of the multitone block 800 of the present invention to eject the same amount of the multitone polymer melt. However, in the present invention, a separate valve 990 is formed at the end of the flow path 817 as shown in Figs. Therefore, if the valve 990 is opened a lot, a large amount of multitone polymer melt will be introduced into the through space 822 between the nozzle 820 and the primary nozzle 850, and if it is opened little, A multi-tone polymer melt may be added to produce coated yarns 12 having different colors.

Next, the present invention as shown in Figure 13, the nozzle 820, the nozzle hole 821 in the form of a dumbbell-shaped, heart-shaped and polygonal to form a coating yarn 12 of various cross-section It is preferable. That is, by forming various shapes of the nozzle hole 821 of the nozzle 820 surrounding the air pocket fiber yarn 10, the coating thickness of the polymer melt and the multitone polymer melt coated on the circular air pocket fiber yarn 10 By varying the cross section is to form a coating yarn 12 of various forms. FIG. 13 shows coated yarns 12 of these various cross-sections, wherein the portion indicated by C in the figures refers to the polymer melt, and the portion indicated by MC refers to the multitone polymer melt.

Indeed, in the present invention, the manner in which the polymer melt is fed along the furnace 62 at the bottom of the block 60 has already been described in the preliminary registration. However, the yarn coating apparatus 2 of this embodiment of the present invention is different from each other in the manner of injecting the multi-tone polymer melt to the multi-tone block (800). That is, injection is performed through the multi-tone polymer melt injector 900 illustrated in FIGS. 10 and 11. Therefore, the configuration and operation of the injector 900 will be described in detail.

The injector 900 has a guide tube 911 formed on the upper end of the multi-stage support 910 in a movable form, and is coupled to the guide tube 911 to provide a work frame in a horizontal direction. There is a 920, there is a rotating motor 921, a reduction gear 922 and a connector 923 coupled to one side of the working frame 920. In addition, there is a hopper 930 coupled to the upper portion of the work frame 920 to accommodate a polymer chip (which can be introduced into the liquid phase), the communication tube 940 communicated in the horizontal direction by communicating at the bottom of the hopper 930 ), And there is a high temperature heater 950 mounted inside the communication tube 940. Therefore, the chips that solidify the multi-tone polymer melt by the heating of the heater 950 are combined to each other, and formed on one side of the multi-tone block 800 through an injection hole 941 formed at the end of the communication tube 940. The multi-tone polymer melt is supplied to the tone polymer melt supply port 802. And the shaft of the reducer 922 existing in the communication tube 940 is formed of a conveying screw 947.

That is, although formed in multiple stages, the guide tube 911 to which the working frame 920 is fastened is formed at the uppermost support 910. Therefore, the guide tube 911 is to be moved in the vertical direction by the support 910. Of course, it also has a stopper (not shown) that can accurately maintain the position if you take the appropriate position, such a vertical movement can be used when the width of the movement distance is narrow. In addition, the work frame 920 is coupled to the guide tube 911 in a state in which a rotation motor 921, a reducer 922, a connector 923, a hopper 930, and a communication tube 940 are fastened. When the guide pipe 911 moves in the vertical direction, the guide tube 911 can move together. That is, the guide tube 911 is appropriately adjusted so that the injection hole 941 of the injector 900 is precisely positioned at the supply hole 802 of the multi-tone block 800 and tightly fastened, and the hopper Inside 930 is filled a multitone polymer melt chip of a desired color. Then, the multi-tone chip in the hopper 930 is pushed into the communication tube 940, and a plurality of high-heat heaters 950 mounted to the communication tube 940 operate to melt the multi-tone polymer chip. When it is melted, the rotating motor 921 rotates, and the reduction screw 922 rotates the feeding screw 947 of the reduction gear 922 to rotate the multi-tone polymer melt to the injection hole 941 at the end. It is a boost. The multi-tone polymer melt pushed out by the force of the transfer screw 947 pushes the melt through the inlet 941 to the supply port 802 formed in the multi-tone block 800 to apply a coating to the air pocket fiber yarn 10. It is. Although not shown, of course, a separate pump or a distribution unit 70 presented in the prior declaration is installed between the injector 900 and the supply port 802 of the multi-tone block 800 to adopt a method of further pushing. You can do it.

Meanwhile, in the present invention, the connector 923 may be a pulley and a belt or a gear and a chain connecting the motor 921 shaft and the reducer 922 shaft to change the rotational force of the motor 921. That is, while transmitting the rotational force of the motor 921 to the reducer 922, a method of switching the rotational force by connecting the connecting method using a pulley and a belt can be used, and can produce the same effect through the gear and the chain. It is. As a result, the present invention transmits the rotational force of the motor 921 to the reducer 922 by using the connector 923 of various known methods.

In addition, the support 910 forms a support plate 918 having a guide tool 917 formed at a lower end thereof, and couples the guide rail 919 through which the guide tool 917 can be moved to a lower end thereof, thereby horizontally interlocking with each other. Do it. As shown, the injector 900 of the present invention can be linked in the vertical direction or in the horizontal direction. Interlocking in the vertical direction is to facilitate easy vertical access to the injector 900 to the multi-tone block 800, but movement in the horizontal direction if the distance between the multi-tone block 800 and the injector 900 of the present invention When it is too far or close to move in the horizontal direction to fix, and to easily mount the present coating device system is all considered to be readily available to the environment of the workplace.

In addition, the inside of the multi-stage support 910, the chain and the gear is engaged, and through the rotation of the motor 970 to enable vertical support of the support 910. That is, as shown in the figure, it does not show the chain and gears inside, but engages the chain and gears inside the support, and the motor is connected to the engagement to extend the multi-stage support 910 through the rotation of the motor To make it possible. This is similar to the vertical movement of the guide tube 911, but the movement of the guide tube 911 allows a small movement of small, and the contraction and expansion of the multi-stage support 910 itself is of a wide vertical direction It is to enable interworking. Of course, as described above, the vertical linkage of the multi-stage support 910 of the present invention is to allow easy vertical access of the injector 900 to the multitone block 800.

[Air pocket coating yarn]

The present invention is also characterized by the coated yarn produced using the air pocket fiber yarn. That is, the coating yarn, which is water produced through the method of the method for preparing the coating yarn, already described above is also characterized.

In the present invention, in the coated yarn, there is an air pocket fiber yarn (10) buried in a state having a constant tension therein, the polymer melt layer (1k) coated with a constant thickness around the outer peripheral surface of the air pocket fiber yarn (10) )this; Bonded, but the coated yarn () having an irregular twisted form by shrinking the polymer melt layer (1k) according to the elasticity of the air pocket fiber yarn (10). The coating yarn 12 of the present invention can be produced by the coating system of the combination of the yarn coating device 1 (100) and the yarn coating device 1, 2 proposed in the present invention, the characteristic part of the irregularly twisted form It can be maintained. In the case of general fiber or coated yarn, it is formed in a long shape and has a constant thickness and diameter, and its elongation or shrinkage is not large. This point is prominent in the case of the coated yarn, in the case of the coated yarn 12 of the present invention, it is possible to have a high elastic air pocket fiber yarn 10 therein. When the polymer melt layer is coated, the air pocket fiber yarn 10 is pulled after the air pocket fiber yarn 10 is already coated before the coating operation. If not, the force will be applied in a direction that reduces its length depending on its resilience. The polymer melt layer 1k applied to the outer circumferential surface will then resist this shrinkage and eventually reshape in a shape that is bent or bent and somewhat warped at an unexpected site. The inner air pocket fiber yarn 10 tries to shrink its length, and the polymer melt layer 1k, which is the outer coating layer, tries to maintain the state, which is a natural result.

The present invention has led to this point. Some natural, proposed natural coating yarn, discarding the obvious symmetrical artificial beauty that was not intended in conventional fiber yarn or coating yarn.

[Fabric manufacturing method using air pocket coating yarn]

The present invention also has a great feature in the fabric manufacturing method woven using the coating yarn 12 described above. That is, in the method of manufacturing the stretch fabric, weaving the weft and the warp with a loom using the high stretch coated yarn 12 having the air pocket 1c coated in a state of given a constant tension, but the state pulled by applying a constant tension It is to weave. The coated yarn 12 produced using the high-stretch air pocket fiber yarn 10 of the present invention is also in a state in which a significant stretch force is given according to the action of the air pocket fiber yarn 10 present therein. This is a unique feature not found in conventional coatings. Therefore, the present invention utilized the characteristics of the coating yarn 12 of the present invention well. In other words, when weaving, a plurality of warp yarns are arranged on the loom in a state where they are pulled with a constant tension in arranging them in a line. And even when using the airjet or waterjet to blow the weft in between the inclined force to be applied to the weft to cross a little taut state. Then, the weft and warp yarns are weaved in a slightly pulled state. After the weaving is completed and the fabric (M), the weft yarn and warp yarns made of the high-stretch coating yarn 12 are each in the direction of reducing their length. To give power. Thus, the fabric M does not cross exactly like a checkerboard like the normal fabric of FIG. 1, but rather achieves an intersection of irregular states as if somewhat crushed or overlapping each other as shown in FIG. This is a very important point in the present invention is that the fabric served by using the intersection of the upper, inclined like a non-woven fabric or a Hanji like a natural pattern.

Something is out of the uniform pattern and shape, and becomes a natural (non-standard) beautiful form of fabric (M). When fabricating functional clothing or a blender and a curtain using the fabric (M), the amount of light transmitted is different for each part of the fabric (M) is excellent visual form and can be used as a more beautiful interior material.

Then, the above-mentioned constant tension, which is important in the present invention, is a force at which an irregular dent of the polymer melt layer 1k on the outer circumferential surface of the air pocket fiber yarn 10 is unfolded. In pulling the air pocket coating yarn 12 while serving, the yarn is pulled to the extent of distorting the form of the uniform weft warp of the fabric M again after being served.

In addition, the present invention may be subjected to a process of fixing the fabric after weaving. In other words, by loosening the tension applied to the force and warmed with 120-180 ° of heat and cooling to fix the shape of the fabric. After weaving the fabric (M) by the elastic recovery force of the coating yarn 12, the fabric (M) itself is slightly twisted, as shown in FIG. Take shape in form. However, if the state is maintained as it is, the resilience of the coating yarn is alive, depending on any external force or humidity change and temperature change, which is likely to be twisted into another form. Of course, such a change may cause problems when made into any finished article, especially a change in size. Such a change may make the object itself unusable, and there is a need to maintain a natural form of the fabric.

To this end, the present invention is to fix the shape of the present natural form through a process of heating and curing with heat of about 120-180 ° in a state where the tension of the woven fabric (M) is released. According to this process, the fabric M of the present invention is a high-quality fabric that can always maintain the naturalness.

[Fabric using air pocket coating yarn]

The present invention has a great feature with respect to the water that is the woven fabric using the air pocket coating yarn described above. That is, in the high-stretch fabric, the air pocket fiber yarn 10 buried in a state having a constant tension therein, and the polymer melt layer (1k) coated with a constant thickness around the outer peripheral surface of the air pocket fiber yarn 10 Air pocket coating yarn 12 made of, and using the coated yarn 12 in a weft and inclined weaving horizontally, vertically overlapping, to maintain the irregular overlapping shape in the stretch of the inner air pocket fiber yarn (10) It is a fabric (M).

The same fabric (M) woven through the air pocket coating yarn fabric manufacturing method described above is also the subject of the present invention. The constitutional feature of this fabric (M) is that the air pocket fiber yarn 10, which is embedded in a pulled state through a constant tension can be crushed to some extent by pulling the polymer melt layer constituting the outer layer, thereby restoring force It is woven into a coating yarn 12 having a. Of course, the coating yarn 12 having such elasticity is also a weaving form in which the upper and the inclined overlap in a state in which a given tension is applied, not through the restoring force of the air pocket coating yarn 10 at the completion of the weaving. It is possible to produce a natural shape of the fabric (M) crushed and overlapping somewhere. In the present invention is to develop such a natural fabric (M).

1 is a view showing a conventional general coating yarn and weaving method,

2 is a view showing a fabric woven with a coating yarn according to the present invention,

Figure 3 is a view of the yarn coating device 1 of the pre-designed design is coated with the flame retardant composition of the present invention,

Figure 4 is a side view of the yarn coating device 1 of the pre-designed design is coated with the flame retardant composition of the present invention,

5 shows a block of the invention,

6 is a view showing a distribution unit of the present invention,

Figure 7 is a view showing a state of the yarn coating device 2 for coating a multi-tone flame retardant coating composition of the present invention,

8 is a view showing a state of the nozzle support of the present invention,

9 is a plan view showing the appearance of the injector of the present invention,

10 is a front view of the injector of the present invention;

11 is a side view of the injector of the present invention,

12 is a view showing the shape of a flow path formed in the multi-tone block of the present invention;

13 is a view showing the shape of the cross section of the coated yarn (= flame retardant yarn) of the present invention,

14 is a view showing a state of coating through the yarn coating apparatus 1, 2 of the present invention.

<Brief description of the major symbols in the drawing shown>

800; Multitone block 801; volt

802; Supply port 820; Nozzle

821; Nozzle hole 830; Fixing member

840; Nozzle support 841; Communicator

842; Stop step portion 850; Primary nozzle

860; Pressure port 900; Multitone polymer injector

911; Guide tube 920; Working frame

921; Rotary motor 922; reducer

923; Connector 930; Hopper

940; Communicator

Claims (9)

In the high stretch coating yarn manufacturing method, First step: towing the air pocket fiber yarn (10) to position in the coating system; Second step: supplying a yarn coating device in a state in which a constant tension is applied to the air pocket fiber yarn (10); The third step: coating the polymer melt into the case 31 of the yarn coating device to a predetermined thickness on the outer peripheral surface of the air pocket fiber yarn (10); The fourth step: a method of manufacturing a high stretch coating yarn having an air pocket, characterized in that it comprises a step of curing the coating yarn 12 that achieved the coating to produce a high stretch coating yarn. The method according to claim 1, The constant tension of the second step is, When the air pocket fiber yarns (10) when walking on the yarn coating device, a high stretch coating yarn manufacturing method with an air pocket, characterized in that the tension is not stretched by its own weight. The method according to claim 1, The yarn coating device, An extrusion mechanism for extruding and applying a polymer melt to an outer circumferential surface of the air pocket fiber yarn 10, in which a plurality of pieces are independently and continuously supplied, and a cooling mechanism for solidifying the polymer melt applied to the air pocket fiber yarn 10. But The extrusion mechanism, A large flow passage 61 through which the extruded polymer melt flows, and a plurality of flow passages 62 formed independently of the large flow passage 61 so that the polymer melt flows out toward the air pocket fiber yarn 10 are provided. Block 60; Each air pocket by connecting the large flow passage 61 to each of the small flow passages 62 and distributing and extruding the polymer melt flowing through the large flow passage 61 in the same amount to each of the small flow passages 62. Method for producing a high stretch coating yarn with an air pocket, characterized in that it comprises a dispensing unit (70) for independently applying the polymer melt to the outer peripheral surface of the fiber yarn (10). The method according to claim 3, The yarn coating device, A case 31 forming a nozzle assembly supplied with the polymer melt under the same pressure into the small flow path 62 formed in the block 60 through the rotational force of the motor 74; A multitone block 800 fastened by a bolt 801 to the upper portion of the case 31 and having a tournament distribution channel 817 through which a multitone polymer melt is moved; The air pocket having a high air pocket, characterized in that it further comprises a multi-tone polymer melt injector 900 for injecting a polymer melt extruded to the multi-tone polymer melt supply port 802 formed on one side of the multi-tone block 800 Stretch coating company manufacturing method. In high stretch coating yarn, Air pocket fiber yarns (10) buried in a state having a constant tension inside the coating yarn; It comprises a polymer melt layer (1k) coated with a predetermined thickness on the outer peripheral surface of the air pocket fiber yarn 10, High stretch coating yarn having an air pocket, characterized in that the polymer melt layer (1k) by the elasticity of the buried air pocket fiber yarn (10) having a certain tension is formed to have an irregular twisted form. In the high stretch fabric manufacturing method, Using the air pocket coating yarn 12 coated with a polymer melt layer 1k on the outer circumferential surface of the air pocket fiber yarn 10 to a certain thickness, weaving the weft and warp of the stretch fabric with a loom, the air pocket fiber yarn Method for producing a high stretch fabric with an air pocket, characterized in that weave in a pulled state by giving a constant tension to (10). The method according to claim 6, The constant tension is The method of manufacturing a highly stretch fabric with an air pocket, characterized in that the polymer melt layer (1k) coated on its outer peripheral surface irregularly twisted by the elasticity of the air pocket fiber yarn (10). The method according to claim 6, After finishing the weaving, loosening the tension given force, and heated to 120-180 ° heat and cooled to fix the shape of the fabric, characterized in that the fabric of high stretch fabric with air pockets. In the high stretch fabric, The air pocket coating yarn 12 made of an air pocket fiber yarn 10 buried in a state having a constant tension therein, and a polymer melt layer 1k coated with a predetermined thickness on the outer circumferential surface of the air pocket fiber yarn 10 is The polymer melt layer 1k is contracted by the stretching action of the air pocket fiber yarn 10 buried in the constant tension state by being used as the weft and the warp yarn of the stretch fabric, and the air pocket coating yarn A highly stretch fabric with an air pocket, characterized in that (12) has an irregularly twisted shape and formed so as to overlap horizontally and vertically.

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