KR101158553B1 - electric spinning apparatus - Google Patents

Abstract

The present invention relates to a centrifugal electrospinning apparatus which can increase productivity by simplifying the construction by electrospinning by rotating centrifugal force and an electric system. Applying a voltage to the centrifugal rotating unit having a spinneret in which spinning liquid is formed, a collector having a negative polarity and collecting the fiber body radiated from the spinning nozzle, a rotating driving unit rotating the centrifugal rotating unit in one direction, and a centrifugal rotating unit And a voltage application means.

The centrifugal rotating part rotates about a rotating shaft extending in an up and down direction, and the collector includes a plate member having a through hole through which the rotating shaft penetrates, and a predetermined length extending upward from an edge of the plate member, thereby extending from the centrifugal rotating part. It is preferable that a skirt member is provided for collecting the fiber to be spun, and the collector is provided with heating means for heating the molten spinning liquid in the centrifugal rotating part.

Centrifugal electrospinning

Description

Electric spinning apparatus

The present invention relates to a centrifugal electrospinning apparatus, and more particularly, to a centrifugal electrospinning apparatus which can increase productivity by simplifying configuration by electrospinning by rotating centrifugal force and electric system.

The spinning process of the fiber refers to a process of continuously pushing the polymer fluid through the thin holes and converting them into long thin fibers. In general, the spinning process is performed by hot polymer fluid coming out of a thin hole called a spinneret, and then cooling and solidifying through a cooling part.

Typical spinning processes include melt spinning and solution spinning.

Melt spinning is a form in which a polymer chip is placed in a raw material storage of a spinning machine, melted in a hot extruder, extruded fibers through a spinneret, solidified by cold cooling air, and then stretched by a winding unit. Solution spinning is dissolved raw material polymer in a solvent in a reservoir, and then passed through a heat exchanger to adjust the molecular weight or viscosity to pass through a spheronet and then to pass through a cold coagulation solution (wet spinning) or to quickly evaporate with hot gas ( Dry spinning) It is a form that is wound around a winding and becomes a fiber.

In recent years, as the cutting-edge nanotechnology is expected to be incorporated into the textile field, much attention has been drawn to the development and application of ultra-fine fibers having a diameter of nano size. Nanofibers are manufactured by electrospinning, which is modified during electrostatic spraying where fine filaments are released from the droplet surface when high tension is applied to the droplets suspended by the capillary ends by surface tension. Fibers are formed when the melt is subjected to electrostatic force.

On the other hand, instead of performing electrospinning alone in terms of radioactivity, productivity, process product characteristics, and the like, methods of mixing the melt spinning and solution spinning have been developed.

For example, Korean Patent Application No. 10-2001-31586 refers to solution spinning and electrospinning, 10-2001-31587 refers to melt spinning and electrospinning, and 10-2002-16489 refers to melt blown ( Melt spinning), a technique that organically combines melt spinning and electrospinning is disclosed. However, these technologies require heating and have problems in stability, or there are many limitations on the raw materials of radiation, and the configuration of spraying compressed air through a separate nozzle is indispensable in designing and managing spinnerets. There was a problem.

The present invention has been made to solve the above problems, and an object thereof is to provide an electrospinning apparatus capable of spinning a large amount of nanofibers using molten plastic used in conventional centrifugal spinning.

Electrospinning apparatus according to the present invention for achieving the above object is an inner body into which the plastic raw material for fiber production and input, the outer body is formed to surround the inner body, the inner body into the inner body The heating medium supply unit for supplying the heated heating medium for melting the plastic raw material stored in the storage, the injection nozzle for injecting the molten plastic and installed in the lower portion of the inner body, and the solidification of the molten plastic passing through the injection nozzle Nozzle heating means for heating the injection nozzle, a conveyor for carrying the plastic fibers to be injected and installed under the injection nozzle, a positive voltage applied to the injection nozzle, and a negative voltage applied to the conveyor. An application means is provided.

The outer body includes a first chamber surrounding the inner body, a second chamber coupled to a lower portion of the first chamber, surrounding the injection nozzle, and having injection holes punched to protrude outward from the end of the injection nozzle. The heat medium supply unit includes a first heater for heating the heat medium, and a circulation pipe connected to the inlet and the outlet of the first chamber so that the heat medium heated by the first heater circulates through the interior of the first chamber. And, it is preferable to have a circulation pump installed on one side of the circulation pipe to pump the heat medium.

The nozzle heating means includes a compressor for blowing air into the second chamber, and a second heater for heating the air supplied by being installed on a pipe of a supply pipe connecting the compressor and the second chamber. It is desirable to.

The electrospinning apparatus according to the present invention has the advantage of being simple in construction and capable of producing large quantities of small diameter fiber bodies.

Hereinafter, with reference to the accompanying drawings will be described in more detail the electrospinning apparatus according to the present invention.

1 and 2, a preferred embodiment of the electrospinning apparatus 100 according to the present invention is shown in a conceptual view and a perspective view, respectively.

Referring to the drawings, the electrospinning apparatus 100 includes a raw material tank 110 for supplying a plastic raw material for nanofiber production, an inner body 120 for storing and melting the plastic raw material supplied from the raw material tank 110; , The spray nozzle 125 formed on the lower portion of the inner body 120, the outer body 130 surrounding the inner body 120 and the spray nozzle 125, and a heat medium supply unit 140 for melting the plastic raw material. ), Nozzle heating means for heating the injection nozzle 125, a conveyor 160 for collecting and transporting the spun plastic fibers, and a voltage applying means for applying a voltage to the injection nozzle 125 and the conveyor 160. And 170.

The inner body 120 is formed of a metal capable of heat transfer, the inner space 121 is provided with a predetermined amount of the plastic raw material can be stored and melted.

Therefore, the plastic raw material of the solid state for fiber production from the raw material tank 110 is introduced into the inner body (120).

The inner body 120 is connected to the gas supply pipe 152, 122 is supplied with a pressurized gas for pressurizing the molten plastic so that the molten plastic can be radiated through the injection nozzle 125 to be described later, the inside The pressure pump 123 for increasing the internal pressure of the main body 120 is connected. And the pressure control valve 124 is provided for the adjustment of the pneumatic pressure supplied from the pressure pump 123, through the pressure control valve 124 to adjust the internal pressure of the inner body 120, through It will control the spinning speed and radiation dose.

The injection nozzle 125 is formed at the lower end of the inner body 120 so as to spray the molten plastic toward the lower conveyor 160.

The outer body 130 includes a first chamber 131 surrounding the inner body 120 and a second chamber 135 surrounding the injection nozzle 125.

The first chamber 131 is installed such that the inner circumferential surface is spaced apart from the outer circumferential surface of the inner body 120 by a predetermined distance, and the moving passage 132 through which the heat medium to be described later can move between the inner body 120 and the first chamber 131. ) Is formed, and an inlet 133 and an outlet 134 are formed to allow the heat medium to flow into or out of the first chamber 131, respectively.

The cover member 137 is coupled to the upper portion of the first chamber 131 to prevent the heat medium from leaking to the outside or the pressure of the pressure pump 123 flowing into the inner body 120 to leak.

The second chamber 135 is connected to the lower end of the first chamber 131 and surrounds the injection nozzle 125.

In the bottom surface of the second chamber 135, the injection nozzle 125 has an injection hole 136 formed so that an end thereof protrudes to the outside.

The heat medium supply unit 140 supplies the heat medium to the inside of the first chamber 131 to melt the plastic raw material stored in the inner body 120.

The heat medium supply unit 140 includes a heat medium tank 141 in which a predetermined amount of heat medium can be stored, a first heater 142 for heating the heat medium stored in the heat medium tank 141, and a heat medium tank 141 and a first heat medium. A circulation pipe 143 interconnecting the chamber 131 and a circulation pump 144 installed in the circulation pipe 143 to circulate the heat medium.

When the first heater 142 is driven to heat the heat medium stored in the heat medium tank 141, the heat medium circulates along the circulation pipe 143 by the circulation pump 144. And since the circulation pipe 143 is connected to the inlet 133 and the outlet 134 of the first chamber 131, respectively, the heat medium flows into the first chamber 131 to heat the inner body 120. After the discharge from the first chamber 131, the inner body 120 is heated by the heat medium so that the stored plastic raw material is melted.

The heat medium may be a gas or air that is easy to heat exchange, or a fluid may be applied.

The nozzle heating means 150 is for preventing the molten plastic injected through the injection nozzle 125 from solidifying in the injection nozzle 125 and supplies heated air to the inside of the second chamber 135. do.

The nozzle heating unit 150 includes a compressor 151 for supplying air to the second chamber 135, a supply pipe 152 connected to the second chamber 135 to supply air, and a pipe line of the supply pipe 152. And a second heater 153 installed to heat the air moving through the supply pipe 152.

Therefore, since the heated air is continuously supplied into the second chamber 135, the injection nozzle 125 is heated by the heated air to prevent the molten plastic from solidifying inside the injection nozzle 125. have.

The supplied heated air is discharged to the outside through the injection hole 136. Since the injection hole 136 is formed toward the outer circumferential surface from the inner circumferential surface of the second chamber 135, the diameter is gradually narrowed. The air discharged from the end of the hole 136 is rapidly expanded to induce the molten plastic to be injected into a fiber in the injection nozzle (125).

The conveyor 160 collects the plastic fibers injected from the injection nozzle 125 and moves them to one side, and a winding roller 161 to which the plastic fibers conveyed by the conveyor 160 are wound on one side thereof. It is prepared.

The voltage applying means 170 is to apply a negative voltage and a positive voltage to the conveyor 160 and the injection nozzle 125, respectively, the plastic fiber injected from the injection nozzle 125 by the voltage applying means 170 is a conveyor It is seated at 160.

The electrospinning apparatus 100 according to the present invention can manufacture a large amount of nanofibers by discharging molten resin through a nozzle.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1 is a conceptual diagram of an electrospinning apparatus according to the present invention,

2 is a perspective view of the electrospinning apparatus of FIG.

<Explanation of symbols for the main parts of the drawings>

100; Electric radiator

110; Raw material tank

120; Internal body

125; Spray nozzle

130; External body

140; Heating medium supply unit

150; Nozzle heating means

160; conveyor

170; Voltage application means

Claims (3)

An inner body into which plastic raw materials for fiber production are input and stored; An outer body formed to surround the inner body; A heat medium supply unit for supplying a heated heat medium to melt the plastic raw material stored in the inner body into the outer body; An injection nozzle installed at the lower part of the inner body and for injecting molten plastic; Nozzle heating means for heating the injection nozzle to prevent solidification of the molten plastic passing through the injection nozzle; A conveyor for transporting plastic fibers which are installed below the spray nozzles and sprayed; And a voltage applying means for applying a positive voltage to the injection nozzle and applying a negative voltage to the conveyor. The outer body includes a first chamber surrounding the inner body, a second chamber coupled to a lower portion of the first chamber, surrounding the injection nozzle, and having injection holes punched to protrude outward from the end of the injection nozzle. and, The heat medium supply unit includes a first heater for heating the heat medium, a circulation pipe connected to an inlet and an outlet of the first chamber so that the heat medium heated by the first heater circulates through the inside of the first chamber; Is installed on one side of the circulation pipe and provided with a circulation pump for pumping the heat medium, The nozzle heating means includes a compressor for blowing air into the second chamber, and a second heater for heating the air that is installed on a conduit of a supply pipe connecting the compressor and the second chamber. , And the injection hole of the second chamber is formed to have a smaller diameter as the air discharged through the injection hole extends from the inner circumferential surface of the second chamber toward the outer circumferential surface so as to rapidly expand at the end of the injection hole. delete delete

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