KR102481109B1 - Nano fiber manufacturing equipment - Google Patents

Abstract

In order to solve the above problems, the present invention is a nanofiber generating device including an air nozzle through which high-speed, high-temperature jet air is discharged and a polymer spinning machine through which molten polymer solution is discharged, and a collector for collecting the generated nanofibers. An object of the present invention is to provide an apparatus for manufacturing nanofibers having a feature in which a streamlined guide portion for inducing them to move is formed to utilize the Coanda effect.
According to an embodiment of the present invention, one or more nanofiber generators including an air nozzle through which high-speed, high-temperature jet air is discharged and a polymer spinning device through which molten polymer solution is discharged, and a solution main tank connected to one side of the polymer spinning machine through a conduit. and a collector rotatably installed at a predetermined distance from the air nozzle in a direction in which the air nozzle extends, and a streamlined guide part installed in a peripheral portion where the high-speed, high-temperature jet air and the polymer solution are extended.

Description

Nano fiber manufacturing equipment {Nano fiber manufacturing equipment}

The present invention relates to a nanofiber manufacturing apparatus,

Nanofiber is an ultra-fine thread with a diameter of only tens to hundreds of nanometers, and it is a high-tech material with a thickness of only about 1/500 of the thickness of a human hair. Nanofibers use various polymer materials as raw materials depending on their use, but the method of pulling out the yarn is the same. A method of manufacturing fibers by extruding a polymer melt under high pressure and applying heated high-speed air to the melt is called an air jet spinning nanofiber manufacturing method. When the high-pressure polymer material is pressed under high pressure and the polymer melt is released through the nozzle, high-speed, high-temperature jet air is sprayed to agglomerate the molecules and split them into nano-sized threads, resulting in 10 to 1,000 nanometer thin threads. The nanothreads move to the collector through guide induction, and the nanothreads are entangled with each other to become a cloth by simply gathering them together without a separate weaving process.

More specifically, the Coanda effect for producing nanofibers and smoothly collecting nanofibers by stretching the polymer solution by discharging high-speed and high-temperature jet air toward the discharged polymer solution at the same time as discharging the molten polymer solution It relates to a nanofiber manufacturing apparatus in which a streamlined guide portion is formed.

Unless otherwise indicated herein, material described in this section is not prior art to the claims in this application, and inclusion in this section is not an admission that it is prior art.

In general, nanofibers are used in many application fields because they have a high surface area to volume ratio and excellent flexibility for surface functional groups.

Methods for manufacturing nanofibers include drawing, template synthesis, phase separation, self assembly, electrospinning, air-jet, etc. .

In particular, as a method for continuously mass-producing nanofibers from various polymers among the nanofiber manufacturing methods, the air jet spinning method is widely applied. Air jet spinning is a technology for producing fine-diameter fibers by spinning a fiber raw material solution, and is used as a technology for producing nanometer-level fibers, and research on this is being actively conducted. The air jet spinning method is manufactured by discharging a spinning material into the air through a spinning nozzle and drawing a fiber raw material solution in the air.

As an example of prior art related to a nanofiber manufacturing apparatus for manufacturing nanofibers using an air jet spinning method and using an air nozzle for firing high-speed, high-temperature air and a jetting nozzle for discharging a fiber raw material solution, Japanese Patent Registration JP 6463733 B2 (2019.01.11) "Nanofiber manufacturing device" has been disclosed.

The disclosed nanofiber manufacturing apparatus is formed of a configuration such as a solution storage unit for storing a solution, a metering pump for quantitative supply of the solution, a plurality of nozzles for discharging the solution, and a collector located opposite to the nozzle and integrating the spun fibers. . Material properties such as the concentration of the radiation material, dielectric properties, and surface tension that determine the characteristics of the nanofiber, the distance between the nozzle and the collector, the high-speed and high-temperature air between the nozzle and the collector, the electric field charge density, and the injection speed of the radiation material variables exist.

The produced fiber has a nanometer thickness in diameter, and when the thickness is reduced, characteristics such as an increase in the surface area to volume ratio, improvement in surface functionality, and improvement in mechanical properties such as tension appear. Due to these excellent properties, nanofibers can be used in various fields of application. Therefore, the web composed of nanofibers can be used in various fields such as various filters, wound treatment dressings, artificial scaffolds, etc. as a porous membrane-type material.

The nanofiber manufacturing technology according to the prior art uses a single or a small number of nozzles, and has difficulties in commercialization, such as a very low production rate and a guide portion between the nozzle and the collector being applied as an obstacle to the flow of the nanosilver.

1. Japanese registered patent JP 6463733 B2 (2019.01.11)

In order to solve the above problems, the present invention is a nanofiber generating device including an air nozzle through which high-speed, high-temperature jet air is discharged and a polymer spinning machine through which molten polymer solution is discharged, and a collector for collecting the generated nanofibers. An object of the present invention is to provide a nanofiber manufacturing apparatus having a feature in which a streamlined guide portion for inducing them to move is formed to utilize the Coanda effect.

In addition, it is not limited to the technical problems as described above, and it is obvious that other technical problems may be derived from the following description.

One or more nanofiber generators including an air nozzle through which high-speed, high-temperature jet air is discharged and a polymer spinning device through which a molten polymer solution is discharged according to an embodiment of the present invention, and a solution main tank connected to one side of the polymer spinning machine through a conduit. and a collector installed rotatably spaced apart from the air nozzle by a predetermined distance in an extension direction of the air nozzle, and a streamlined collector installed in a periphery where the high-speed, high-temperature jet air and polymer solution are extended.

According to a preferred feature of the present invention, the guide portion is characterized in that one side is open and a hollow portion is formed with a predetermined space therein.

According to a preferred feature of the present invention, it is characterized in that the heating portion is formed to be closely coupled to the inner circumferential surface of the hollow portion.

According to a preferred feature of the present invention, it is characterized in that the air nozzle and the polymer emitter form a multi-block corresponding to each other and coupled in plurality.

According to a preferred feature of the present invention, the multiple blocks are characterized in that they are coupled to one side of a block frame in which a predetermined space is formed.

According to the present invention, in the process of producing nanofibers by spinning high-speed, high-temperature jet air in a polymer solution, the distance between spinning nozzles can be adjusted to prevent distortion by controlling the speed, temperature, and pressure of the air in the nozzle. Since it is possible, there is an effect of having effective process conditions. It is possible to form a block by arranging a plurality of nozzles, and by controlling the amount of polymer spinning solution supplied to each nozzle tube and the amount of spinning polymer spinning solution spun from each nozzle, nanofibers having an even distribution on the same plane It is possible to include

Instead of a guide member to prevent the nanofibers that are aggregated into the existing collector from escaping to a place other than the collector, a streamlined guide part using the Coanda effect, which can act as a guide member, is used to prevent the nanofibers from escaping and to direct the nanofibers in the desired direction. It is possible to flow the fibers. The Coanda effect is a phenomenon in which airflow ejected from approaching a wall or ceiling surface attaches to the surface and flows. Therefore, while moving along the outer circumferential surface of the guide unit, it is possible that the nanofibers are guided toward the collector while falling from the distal end.

In addition, it is possible to improve the manufacturability of nanofibers, and nanofibers have the advantage of being able to secure excellent quality. It is possible to expand and change the manufacturing unit and the guide structure, thereby increasing production volume.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the detailed description of the present invention or the configuration of the invention described in the claims.

1 is a front view of a nanofiber manufacturing apparatus according to an embodiment of the present invention.
Figure 2 is a perspective view of the guide unit of the nanofiber manufacturing apparatus according to an embodiment of the present invention.
Figure 3 is a front view of a nanofiber manufacturing apparatus according to another embodiment of the present invention.
Figure 4 is a side view of the block frame of the nanofiber manufacturing apparatus according to another embodiment of the present invention.
Figure 5 is a schematic block diagram of the operating sequence of the nanofiber manufacturing apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, look at the configuration, operation and effect of the nanofiber manufacturing apparatus according to a preferred embodiment. For reference, in the drawings below, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size. In addition, like reference numerals refer to like components throughout the specification, and reference numerals for like components in individual drawings will be omitted.

1 shows a front view of a nanofiber manufacturing apparatus according to an embodiment of the present invention, and FIG. 2 shows a perspective view of a guide unit of the nanofiber manufacturing apparatus.

Figure 3 shows a front view of a nanofiber manufacturing apparatus according to another embodiment of the present invention, Figure 4 shows a side view of the block frame of the nanofiber manufacturing apparatus.

Figure 5 shows a block diagram schematically illustrating the operating sequence of the nanofiber manufacturing apparatus according to an embodiment of the present invention.

Nanofiber manufacturing apparatus 1 according to an embodiment of the present invention,

One or more nanofiber generators (4) including an air nozzle (2) through which high-speed, high-temperature jet air is discharged and a polymer spinning device (3) through which a molten polymer solution is discharged are connected to one side of the polymer spinning device (3) through a conduit. A solution main tank (not shown) and a collector (5) rotatably installed apart from the air nozzle (2) at a predetermined distance in the direction of air nozzle extension, and a peripheral portion in which the high-speed, high-temperature jet air and the polymer solution are extended. It includes a guide part 6 in the form of a streamline.

Here, in the space between the air nozzle 2 and the collector 5, the high-speed, high-temperature jet air discharged from the air nozzle 2 and the polymer solution discharged from the polymer spinning machine 3 meet and stretch. In addition, the polymer solution is evaporated and stretched, and nanofibers are formed and transferred toward the collector 5 to be attached. Because of this, the nanofibers move toward the collector 5 without escaping to the outside due to the Coanda effect on the surface. The Coanda effect is a phenomenon in which airflow ejected from approaching a wall or ceiling surface attaches to the surface and flows. Therefore, the high-speed, high-temperature jet air is discharged from the air nozzle 2 toward the collector 5, and the high-speed, high-temperature jet air moves along the outer circumferential surface of the guide part 6 and moves like nanofibers formed, and then the guide part ( 6) It is possible to guide nanofibers toward the collector 5 from one end.

The guide portion 6 may have a hollow portion with one side open and a predetermined space formed therein.

Here, when the nanofibers and high-speed, high-temperature jet air flow along the surface of the guide part 6, and the high-speed, high-temperature jet air cools down and the heat drops, the nanofibers are attached to the surface of the guide part 6 and the flow stops. occurs. Therefore, the guide part 6 has one side open and has a hollow part by forming a predetermined space therein, and it is possible to insert a configuration capable of generating heat in the hollow part. In addition, it is possible to combine a structure that prevents nanofibers from being attached to the surface of the guide part 6 even if it is not a heat generating mechanism.

It is possible to form a heating unit 7 closely coupled to the inner circumferential surface of the hollow part.

Here, the predetermined space of the hollow formed in the guide part 6 may be made of a circular through hole, and the heating part 7 is closely coupled along the inner circumferential surface of the through hole to generate heat so that the guide part 6 It is possible to allow heat to be transferred to the outer circumferential surface of the

It is possible to form a multi-block 9 in which the air nozzle 2 and the polymer emitter 3 correspond to each other and are combined in plurality.

Here, in order to generate nanofibers, the air nozzle 2 and the polymer emitter 3 are configured to correspond to each other so that it is possible to form a pair to effectively generate nanofibers. It is possible to configure the multi-block 9 by combining a plurality of them, and the multi-block 9 can be formed in a rectangular or circular shape, and the rectangular multi-block 9 protrudes in the collector direction at the periphery of the streamlined guide. The part 6 is located, and the circular multi-block 9 has a streamlined guide part 6 protruding in the direction of the collector at the center of the circular shape, and the nanofibers and high-speed high-temperature jets formed in the multi-block 9 are located. It is possible for air to flow on the surface of the guide part 6 and then flow toward the collector 5 at one end.

The multi-block 9 can be coupled to one side of a block frame 8 in which a predetermined space is formed.

Here, when the nanofiber generating device 4 generates nanofibers singly, since the amount is very small, it is possible to form the block frame 8 by connecting a plurality of the multi-blocks 9 for large production. Do. When the high-speed, high-temperature jet air is discharged to the outside of the block frame 8, if it is discharged irregularly, the Coanda effect may not appear properly on the surface of the guide part 6, so the block frame 8 is inside By forming a predetermined space, it is possible to uniformly disperse the high-speed and high-temperature jet air inside and eject it to the outside.

A plurality of conduits connected from the outside are formed so that high-speed, high-temperature jet air can be supplied to each of the air nozzles 2 .

1: Nanofiber manufacturing device
2: air nozzle
3 : Polymer Spinner
4: nanofiber generator
5: Collector
6: guide part
7: heating part
8 : block frame
9: multi-block
P: Nanofiber movement direction

Claims (5)

One or more nanofiber generators including an air nozzle through which high-speed, high-temperature jet air is discharged and a polymer emitter through which molten polymer solution is discharged;
a solution main tank connected to one side of the polymer emitter through a conduit;
a collector rotatably installed at a predetermined distance from the air nozzle in an extension direction of the air nozzle; and
Including; a guide part in the form of a streamline installed in the periphery where the high-speed, high-temperature jet air and the polymer solution are stretched,
The guide part has one side open and a hollow part having a predetermined space formed therein,
Nanofiber manufacturing apparatus, characterized in that the heating unit is formed in close contact with the inner circumferential surface of the hollow part. delete delete According to claim 1,
Nanofiber manufacturing apparatus, characterized in that the air nozzle and the polymer emitter form a multi-block corresponding to each other and combined in plurality. According to claim 4,
The multi-block nanofiber manufacturing apparatus, characterized in that coupled to one side of the block frame in which a predetermined space is formed therein.

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