KR20150004170A - Electrospinning apparatus - Google Patents

Abstract

The present invention relates to an electrospinning apparatus comprising a spinning nozzle with a plurality of needles which spins nanofibers; a thermo-hygrostat unit which is installed between the spinning nozzles arranged in plurality of rows and directly sprays thermo-hygrostat air to the nanofiber released from the spinning nozzle; a fixing frame in which the spinning nozzles and the thermo-hygrostat units are fixed in turn; and a collector which is installed on the lower side of the spinning nozzle and forms nanowebs by accumulating nanofibers, thereby improving the quality of the nanoweb and reducing cost because a thermo-hygrostat process is not necessary for all chambers.

Description

[0001] ELECTROSPINING APPARATUS [0002]

The present invention relates to an electrospinning apparatus, and more particularly to an electrospinning apparatus having a partial temperature and humidity / humidity unit.

Generally, an electrospinning apparatus is a device for forming a nanofiber by electrospinning a spinning solution in which a polymer material and a solvent are mixed at a predetermined ratio through a spinneret, and accumulating nanofibers to form a plurality of pores.

The conventional electrospinning apparatus is provided with a needle portion for discharging a fiber raw material liquid at a lower portion thereof as disclosed in Patent Document 10-2010-0133524 (December 22, 2010) A nozzle liquid supply passage for supplying the liquid raw material to the inside of the nozzle member, and a second air supply passage for supplying and discharging air from the first nozzle A first nozzle body member on which a flow path is formed, an insertion portion detachably coupled to a lower portion of the first nozzle body member, in which the nozzle member is inserted and an injection port is opened downwardly, A second nozzle body member having a second air passage for communicating the first nozzle body member and the second nozzle body member; An air supply unit for supplying air to the first air passage of the first nozzle body member; a second air supply unit for supplying air to the first air flow channel of the first nozzle body member; And a collector for collecting the spun fibers in a web state.

Such a conventional electrospinning device is installed inside the chamber, and since the nanofibers to be radiated are sensitive to temperature and humidity, the temperature and humidity inside the chamber must be kept constant at all times.

Therefore, the constant temperature and humidity device is connected to the chamber to keep the temperature and humidity inside the chamber constant.

However, when the inside of the chamber is subjected to constant temperature and humidity, the temperature and humidity of the entire chamber must be kept constant, so that the capacity of the constant temperature and humidity device becomes large and the cost increases.

In addition, when the electric shielding apparatus is enlarged in size, the size of the chamber is also increased. When the entire interior of the large chamber is subjected to constant temperature and humidity, the temperature and humidity of the inside of the chamber are different, have.

Published Patent Application No. 10-2010-0133524 (December 22, 2010)

It is an object of the present invention to provide a thermo-hygrostat unit between each spinning nozzle to directly spray the thermo-hygroscopic air to the nanofibers emitted from the spinning nozzle, And to provide an electrospinning device capable of improving the quality of the electrospinning device.

Another object of the present invention is to provide an electrospinning device capable of reducing cost because the temperature and humidity unit is provided on the side surface of each spinning nozzle and the temperature of the entire nanofiber is directly and constantly controlled by controlling the temperature and humidity of the nanofibers radiated from the spinning nozzle. will be.

To achieve the above object, an electrospinning device of the present invention includes a plurality of spinning nozzles each having a plurality of needles for spinning nanofibers, a plurality of spinning nozzles arranged in a plurality of rows, a spinning nozzle disposed between the spinning nozzles, A plurality of thermo-hygrostat and humidity units for spraying air directly subjected to constant temperature and humidity to the nanofibers, a frame in which the spinning nozzle and the thermo-hygrostat unit are alternately fixed, and a frame disposed below the spinning nozzle and accumulating nanofibers Collector.

According to a preferred embodiment of the present invention, the spinning nozzle is connected to a mixing tank in which a polymer material and a solvent are stored, and is connected to a high voltage generator to apply a high voltage electrostatic force between the collector and the spinneret.

The thermo-hygrostat unit may include a body fixed to the frame and having an air passage formed therein, and a thermo-hygrostat air blower installed at a lower surface of the body to have a predetermined inclination angle, And a second jet port formed on the lower surface of the body at a predetermined inclination angle in the other direction and jetting the thermo-hygroscopic air to the nanofibers emitted from the spinneret disposed on the other side.

In addition, the air passage may be equipped with a nonwoven fabric having a plurality of pores for evenly distributing the air introduced into the air passage.

As described above, in the electrospinning apparatus of the present invention, the thermo-hygrostat unit is installed between the respective spinning nozzles, and the thermo-hygroscopic air is sprayed directly onto the nanofibers emitted from the spinning nozzle, It is possible to improve the quality of the nano web.

In the electrospinning apparatus of the present invention, since the temperature and humidity unit is installed between each spinning nozzle, the nanofibers radiated from the spinning nozzle are directly subjected to constant temperature and humidity control, and the cost can be reduced because the entire chamber is not subjected to constant temperature and humidity.

1 is a configuration diagram of an electrospinning device according to an embodiment of the present invention.
2 is a rear view of an electrospinning device according to an embodiment of the present invention.
3 is a perspective view showing a constant temperature and humidity unit of an electrospinning device according to an embodiment of the present invention.
4 is a sectional view taken along line AA in Fig.
5 is a cross-sectional view of the BB line in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

1 is a side view of an electrospinning device according to an embodiment of the present invention.

Referring to FIG. 1, an electrospinning apparatus according to an embodiment of the present invention includes a plurality of spinning nozzles 10 having a plurality of needles 12 to form nanofibers, and a plurality of spinning nozzles 10 A plurality of thermo-hygrostat units 30 disposed between the spinning nozzles 10 for directly injecting the air subjected to constant temperature and humidity into the nanofibers; And a collector 40 for accumulating nanofibers radiated from the spinning nozzle 10 to form a nano-web.

Here, the spinning nozzle to which the present invention is applied includes general electrospinning, air-electrospinning (AES), electrospray, electrobrown spinning, centrifugal electrospinning, , And flash-electrospinning may be used.

The spinning nozzle 10 is connected to a mixing tank 14 in which a polymer material and a solvent are mixed and stored so that the spinning solution is supplied to the spinning nozzle 10 and connected to the high voltage generator, By applying a high voltage electrostatic force of 90 to 120 Kv between the nozzles 10, the nanofibers 16 are radiated to form a nanoweb.

A film roll 52 for supplying the release film 50 to the collector 40 is provided in front of the collector 40 and a pressure roller 54 for pressing the nano- And a sheet roll 56 on which the nano web pressed by the pressure roller 54 is wound is provided.

2, the frame 20 includes a first fixing part 22 disposed on the upper side of the collector 40 and provided with the spinning nozzle 10 and a second fixing part 22 provided with the constant temperature and humidity unit 30, And the gate 24 are formed alternately and repeatedly.

The frame 20 is connected to a driving device (not shown), and linearly reciprocates in the front, rear, and left and right directions to uniformly radiate the nanofibers to the front surface of the collector 40.

The constant temperature and humidity unit 30 is connected to a constant temperature and humidity device 60 for generating constant temperature and humidity air and a supply hose 62 to be supplied with constant temperature and humidity air and a pump 64 is installed at one side of the supply hose 62 The air is pumped at constant temperature and humidity so that the constant temperature and humidity air is sprayed in the constant temperature and humidity unit (30).

The constant temperature and humidity device (60) uses a heat exchanger to heat or cool the air to maintain a constant temperature, and a dehumidifier and a humidifier are provided to maintain a constant humidity. The control unit controls the heat exchanger, the dehumidifier, and the humidifier so that the temperature and humidity of the air supplied to the constant temperature and constant humidity unit are always kept constant.

As described above, the constant temperature / humidity device (60) can be applied to any device capable of generating constant temperature and humidity air to the nanofibers.

3 and 5, the constant temperature / constant humidity unit 30 includes a body 36 in which an air passage 38 is formed and is fixed to the second fixing portion 24 of the frame 20, (36) and jetting ports (32, 34) for spraying the constant temperature and humidity air onto the nanofibers.

The body 36 has the same length as that of the spinneret 10 and a suction hose 62 is connected to the upper surface of the body 36 to form a plurality of suction ports 72 in the longitudinal direction to which the constant temperature and humidity air is supplied.

The air passage (38) is formed in a plurality of sections in the longitudinal direction of the body (36). 5, a plurality of air passageways 38 are formed at regular intervals in the longitudinal direction of the body 36, and a pair of supply hoses 62 are formed in each air passageway 38 .

Since the body 36 has the same length and the same length as the spinning nozzle 10, if the air passage 38 is connected as a whole, the air discharge amount varies depending on the position, and accordingly, There is a fear that the humidity and air quality will be deteriorated and the quality may be deteriorated.

In this embodiment, since the air passage 38 is divided into a plurality of air passages 38 in the longitudinal direction of the body 36, the discharge amount of the constant temperature and humidity air injected from each air passage 38 can be kept constant, The amount of air injected into the nano web can be kept constant and the quality of the nano web can be improved.

The air passage (38) is provided with a nonwoven fabric (70) having a plurality of pores for evenly distributing the air introduced into the air passage (38). That is, the constant temperature and humidity air introduced into the air passage 38 through the inlet port 72 is uniformly distributed over the entire surface by the nonwoven fabric 70 and then injected through the injection ports 32 and 34, The same amount of air can be injected over the entire surface of the nozzle.

The injection ports 32 and 34 are connected to the air passage 38 and are formed to have a predetermined inclination angle to the left side of the body 36. The injection ports 32 and 34 are made of a material for spraying the constant temperature and humidity air to the nanofibers radiated from the spinneret 10, And a second ejection opening 34 for ejecting the constant temperature and humidity air to the nanofibers radiated from the spinning nozzle 10 which is formed at the right side of the body 36 at a predetermined inclination angle and is located on the right side .

Since the first injection port 32 and the second injection port 34 are formed at a constant inclination angle in the thermo-hygrostat unit 30, the constant temperature and humidity air is injected in the same direction as the arrow P, It is in direct contact with the fibers.

Since the first injection port 32 and the second injection port 34 are formed on both sides of the single temperature and humidity unit 30, the nanofibers radiated from the spinning nozzle 10 are brought into contact with the constant temperature and humidity air on both sides thereof The contact area between the nanofibers and the constant-temperature and constant-humidity air can be increased, thereby improving the quality of the nanofibers.

The operation of the electrospinning device according to one embodiment of the present invention thus constructed will be described below.

First, when the collector 40 is driven, the release film 50 is supplied to the upper surface of the collector 40.

By applying a high voltage electrostatic force between the collector 40 and the spinning nozzle 10, the spinning solution is made into nanofibers 16 in the spinning nozzle 10 and is radiated onto the surface of the release film 50. Then, the nanofibers 16 are accumulated on the surface of the release film 50 to form a nano-web having a plurality of pores.

At this time, the constant temperature and humidity air is sprayed directly to the nanofiber 16 in the constant temperature and humidity unit 30 disposed between the spinning nozzles 10. Then, the nanofiber 16 can maintain a constant temperature and a constant humidity, thereby improving the quality of the nano-web accumulated in the collector 40.

Temperature and humidity air is generated in the constant temperature and humidity device (60) and supplied to the air passage (38) of the constant temperature and constant humidity unit (30) through the supply hose (62). The air introduced into the air passage 38 is uniformly distributed through the nonwoven fabric 70. The air is circulated through the first injection port 32 and the second injection port 34, The nanofibers positioned at the right side are sprayed with constant-temperature and constant-humidity air to constantly heat and humidity the nanofibers.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

10: injection nozzle 12: needle
14: mixing tank 16: nanofiber
20: frame 22: first fixing part
24: second fixing unit 30: constant temperature and humidity unit
32: first jetting port 34: first jetting port
36: Body 38: Air passage
40: Collector 50: Release film
60: constant temperature and humidity device 62: supply hose
70: Nonwoven fabric

Claims (7)

A plurality of spinnerets arranged in a plurality of rows, each spinneret having a plurality of needles radiating nanofibers each;
A plurality of constant temperature and humidity units arranged between the plurality of spinning nozzles and spraying air directly and thermally and humidity-regulated to the nanofibers emitted from the spinning nozzle;
A frame in which the spinning nozzle and the constant temperature / constant humidity unit are alternately fixed; And
And a collector disposed below the spinneret and accumulating nanofibers to form a nano-web. The method according to claim 1,
Wherein the spinning nozzle is connected to a mixing tank in which a polymer material and a solvent are stored, and is connected to a high voltage generator to apply a high voltage electrostatic force between the collector and the spinning nozzle. The method according to claim 1,
The unit includes a body fixed to a frame and having an air passage formed therein,
A first jetting port formed at a lower surface of the body to have a predetermined inclination angle in one direction and jetting a constant temperature and humidity air to the nanofibers emitted from a spinning nozzle disposed at one side,
And a second jetting port formed to have a predetermined inclination angle in the other direction on the lower surface of the body and to inject air having constant temperature and humidity into the nanofibers radiated from the spinning nozzle arranged on the other side. The method of claim 3,
Wherein the air passage formed inside the body is divided into a plurality of air passages in the longitudinal direction of the body, and a pair of supply hoses are connected to one air passage. The method of claim 3,
Wherein the air passage is equipped with a nonwoven fabric having a plurality of pores for evenly distributing the air introduced into the air passage. The method according to claim 1,
Wherein the frame is arranged alternately with a first fixing part on which the spinning nozzle is mounted and a second fixing part on which the constant temperature and humidity unit is mounted. A spinning nozzle unit for spinning nanofibers;
A collector in which nanofibers emitted from the spinning nozzle unit are accumulated; And
And a partial temperature and humidity unit for keeping the temperature and humidity atmosphere of the radiation section between the spinning nozzle unit and the collector at a constant level.

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