KR20190122146A - Electrospinning apparatus for making ultra-finefiber improved in structure of controlling a charged solution and transfer pump for the same - Google Patents

Abstract

The present invention relates to an electrospinning apparatus for producing an ultrafine fiber having a structure which can control the direction of charged filaments to produce the ultrafine fiber in a uniform pattern. The electrospinning apparatus comprises: a high voltage supply unit which charges a solution in which a polymer material is dissolved by applying high voltage to a spinning nozzle; a spinning nozzle unit having at least one hollow tube needle for discharging the charged solution to be discharged in a form of filament; a cylindrical metal guide which is arranged to surround the hollow tube needle at the bottom of the spinning nozzle unit and applies the high voltage to control droplet stability of the charged solution; and an integrated unit disposed below the spinning nozzle unit to collect charged filaments.

Description

Electrospinning apparatus for making ultra-finefiber improved in structure of controlling a charged solution and transfer pump for the same}

The present invention relates to an electrospinning apparatus for microfiber production and a solution transfer pump therefor, and more particularly, to an electrospinning apparatus for microfiber manufacturing having a structure capable of producing microfibers in a uniform pattern by controlling the direction of the charged filament and It relates to a solution transfer pump for this.

In general, electrospinning is a device in which an electric field is formed by applying a high voltage of thousands to tens of thousands of volts to a polymer solution and connecting a ground or negative voltage to a collector receiving a charged filament. Refers to a process for producing nanofibers. At this time, the charged droplet discharged through the nozzle is elongated in the longitudinal direction due to the electric force is made of ultrafine fibers of nanometer (nm) to micrometer (μm) diameter.

In the electrospinning process, the high voltage intensity applied to the solution is set differently depending on the type of the polymer solution or the conditions for producing the nanofibers. The applied high voltage intensity is determined by the distance (TCD, in cm) between the nozzle and the integrated plate, polyvinylidene fluoride (PVDF), or polyacrylonitrile (PAN), or poly 0.5 to 1.5 kV / cm for vinyl pyrrolidone (PVP (poly (vinylpyrrolidone)) polymer solution, 1.5 to 2 kV / cm for polyvinyl alcohol (PVA (poly (vinylalcohol)) polymer solution, and chitosan (chitosan) In the case of the polymer solution, it is 3 to 5 kV / cm.

The microfibers produced by the electrospinning process are made of a microporous membrane while being collected and laminated on an integrated plate, or coated with a thin film on a predetermined substrate. In addition, the process of forming the microfibers can be applied to the fabrication of a linear configuration.

In the electrospinning process, the charged filaments forming the nanofibers are prepared from a charge solution discharged from a hollow tube needle (nozzle) under a high voltage, or from a solution coated with a thin film on a roll or wire to which a high voltage is applied.

In the electrospinning process using the nozzle, when the charged filament is formed from the droplet discharged from the nozzle, when an electric force greater than the surface tension of the solution is applied, the droplet of the charged liquid discharged from the nozzle is conical at the nozzle tip. And conical protrusions are stretched in the longitudinal direction toward the integrated plate to form charged filaments. At this time, the cone formed at the tip of the nozzle is called a taylor cone, and the filament elongated in the longitudinal direction is called a jet. Jets produced from the Taylor cone projections are made of nanofibers at any point at higher electrical forces, undergoing sharp wobble mode and solvent volatilization.

The above-mentioned conical Taylor cone shows an unstable state at the nozzle end as the high voltage intensity is high and the solvent volatility is strong. If the Taylor cone is unstable, the charged filament jets formed therefrom also do not maintain orientation and become unstable. As such, when the Taylor cone is unstable at the nozzle end, there is a problem that it is not uniformly integrated at the same position of the lower integrated plate. In addition, it is difficult to repeatedly and consistently produce a microfiber on the substrate, it is difficult to produce a web having the same shape or size.

In addition, when manufacturing the structure of the core shell structure using a coaxial double nozzle, if the Taylor cone formed at the nozzle tip is unstable, it is difficult to produce a structure having a uniform shape because the cone is not formed properly.

If the surrounding radiation environment is asymmetrical in the electrospinning process, the charged filament is affected by the position of the nozzle, so that a constant pattern cannot be produced on the substrate.

On the other hand, in the electrospinning process, the solution reservoir is mainly a syringe (syringe) having a rod-type plunger or a barrel having an inner plunger. The solution filled in the syringe or barrel is transferred to the nozzle by driving a solution transfer device composed of a stepping motor and a pusher, or is injected quantitatively by injecting air or gas. At this time, the high voltage is applied to the solution through the nozzle. However, the conventional method of applying a high voltage to the nozzle has a problem in that the direction of the discharge droplet is deflected to one side due to an electric field asymmetry at the nozzle tip.

In addition, when increasing the distance between the nozzle tip and the integrated plate to increase the high voltage intensity, the droplets of the cone-shaped Taylor cone formed in the nozzle tip represents an unstable state such as severe shaking at the nozzle tip or deflected to one side. If the spinning droplets are unstable, it is difficult to produce a nanofiber film having a uniform thickness because jets of charged filaments formed therefrom are integrated in the integrated plate without constant orientation. In addition, in the case of a polymer solution having a high viscosity or high interfacial tension, nanofibers should be manufactured by increasing the high voltage strength. In this case, when the strength of the high voltage is increased, the solution discharged from the nozzle is radiated to one side and radiated. It is difficult to integrate the fibers in a certain area. In addition, when using a plurality of spinning nozzles, each of the charged filaments discharged from the nozzle is pushed against each other by the charge repulsion, showing an unstable spinning state at the nozzles located at both ends. In addition, when spinning using two solutions, for example, when fabricating a double-layer structure of the core and shell structure, the Taylor cone formed at the nozzle tip may be deflected and radiated because the optimum high voltage intensity is different. In this case, due to the nonuniformity of the core portion and the shell portion, it is difficult to produce a double layer nanofibers having a homogeneous core shell structure.

When the high voltage intensity is increased, the syringe mounted in the solution transfer device may break down and form a high voltage electric field around the pump, and thus the control circuit of the solution transfer device may become uncontrollable due to an instantaneous short circuit. This problem frequently occurs as the high voltage intensity is increased. In particular, in a high voltage environment of 20 kV or more, a short circuit occurs from the metal nozzle mounted outside the syringe or mounted on the syringe to the metal casing of the syringe pump. In a high voltage environment, the syringe mounted on the solution transfer device is insulated and broken, and a high voltage electric field is formed around the pump, and the control circuit part of the solution transfer device becomes uncontrollable due to an electric short circuit.

The present invention was conceived in consideration of the above problems, and controls the droplet stability of the charge solution formed on the nozzle tip under a high voltage environment of tens of thousands of volts, and controls the direction of the charge filament generated therefrom to make the spinning stable and homogeneous It is an object of the present invention to provide an electrospinning apparatus for producing an ultrafine fiber, and a solution transfer pump therefor, in which the charge control solution control structure is improved to manufacture nanofibers.

It is another object of the present invention to provide an electrospinning apparatus for producing ultrafine fibers and a solution transfer pump therefor that are electrically secured without an electrical short circuit of a control circuit part due to a short circuit in a high high voltage environment.

Electrospinning for producing an ultrafine fiber as an aspect of the present invention for achieving the above object is a high voltage providing unit for applying a high voltage to the spinning nozzle to charge the solution in which the polymer material is dissolved; A spinning nozzle unit having at least one hollow tube needle configured to receive a charged solution and discharge the same in a filament form; A cylindrical metal guide disposed at a lower end of the spinneret part to surround the hollow tube needle and to which a high voltage is applied to control droplet stability of the charged solution; And an integrated part disposed below the spinning nozzle part to collect charged filaments.

According to another aspect of the present invention, a solution transfer pump of an electrospinning apparatus for microfiber production includes: a spinning nozzle unit having at least one hollow tube needle for receiving a charged solution and discharging the filament in a filament form; And a cylindrical metal guide disposed to surround the hollow tube needle at a lower end of the spinning nozzle part and to which a high voltage is applied to control droplet stability of the charged solution.

The cylindrical metal guide is characterized in that the lower end is disposed 1 ~ 5mm higher than the tip of the hollow tube needle.

In addition, the microspun fiber electrospinning apparatus as one aspect of the present invention or the solution transfer pump as another aspect of the present invention is a strip-shaped metal plate extending in a direction perpendicular to the nozzle arrangement direction around the cylindrical metal guide. It further comprises a strip-shaped metal guide arranged in a plurality of radially.

The plurality of metal plates may be disposed on the same plane or shifted to have different heights.

In addition, the strip-shaped metal guide may be rotatably installed about the cylindrical metal guide.

The microspun fiber electrospinning apparatus and the solution transfer pump for improving the chargeable liquid control structure according to the present invention has the following effects.

First, it is possible to solve the radiation instability by controlling the shaking of the charged solution formed in the nozzle tip in a high voltage environment of tens of thousands of volts of electrospinning.

Secondly, by disposing a cylindrical metal guide and a strip-shaped metal guide around the hollow tube needle of the spinneret part, the discharge droplets of the charged solution are stably maintained, and the charged filaments formed therefrom maintain a constant orientation with respect to the substrate and are thus extremely fine on the integrated part. A uniform pattern composed of fibers can be produced.

Third, it is possible to electrically protect the solution transfer pump during the electrospinning process by blocking the high voltage leaked from the syringe to the support plate or case to prevent electrical short circuit of the control unit.

The following drawings attached to this specification are illustrative of the preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to.
1 is a front view showing the configuration of an electrospinning apparatus for producing ultrafine fibers according to a preferred embodiment of the present invention.
Figure 2 is a perspective view showing the configuration of the solution transfer pump in FIG.
3 is an exploded perspective view showing the configuration of the spinning nozzle unit and the charge control solution control means in FIG.
4 is a cross-sectional view of the combination of FIG.
5 is a perspective view showing a cartridge type multi-channel solution transfer pump provided according to another embodiment of the present invention.
FIG. 6 is a perspective view illustrating a two-channel solution transfer pump provided according to a modification of FIG. 5.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a front view showing the configuration of an electrospinning apparatus for producing an ultrafine fiber according to a preferred embodiment of the present invention, Figure 2 is a perspective view showing the configuration of the solution transfer pump in Figure 1, Figure 3 is a radiation nozzle portion in Figure 2 And an exploded perspective view showing the configuration of the charge-loading liquid control means, and FIG.

1 to 4, the ultra-spinning fiber manufacturing apparatus according to a preferred embodiment of the present invention, the high voltage providing unit 110 for applying a high voltage to the supplied raw material polymer solution by applying a high voltage to the spinning nozzle unit 120 ), A solution transfer pump 100 for transferring the solution stored in the syringe 108 toward the spinning nozzle unit 120, and an integration unit 140 for collecting the charged filaments. In addition, the solution transfer pump 100 includes a spinning nozzle unit 120 for discharging the charged filament, a cylindrical metal guide 116 and a strip-shaped metal guide disposed below the spinning nozzle unit 120 as a charge control solution. 114).

The syringe 108 preferably includes a container barrel having an internal capacity of 100 µl to 1,000 ml. A plunger 107 corresponding to a straw is inserted into the container barrel portion of the syringe 108. In the case of the internal storage tank without the plunger 107, the solution may be transferred by air pressure. The syringe 108 is preferably made of an insulating material such as polypropylene (PP), polyethylene (PE), polyether ether ketone (PEEK), nylon (Nylon), acetal, and glass having excellent voltage resistance. In the case of an insulator having a thin thickness, the insulation may be destroyed at high voltage during the electrospinning process, or the electricity of the charge-discharge liquid may be discharged to the outside of the syringe 108 at the connection portion, so that an outer cover of the insulating material is used together. It is preferable.

The polymer solution to be injected into the syringe 108 may be polyvinylidene fluoride (PVDF (poly (vinylidene fluoride)), polyacrylonitrile (PAN (poly (acrylonitile)), polyvinyl alcohol (PVA (poly (vinylalcohol))) Polyimide (PI), polyethylene oxide (PEO), polylactic-co-glycolic acid (PLGA), polylactic acid (PLA) polylactic acid), polylactic acid (PLLA (poly-L-lactic acid)), polyglycolic acid (PGA (polyglycolic acid)), polycaprolactone (PCL (polycarpro lactone), chitosan (chitosan) A solution containing a polymer to be dissolved or a polymer solution including conductive particles may be applied.

In the case of manufacturing a core-shell double layer structure, the polymer solution may be employed as the shell solution, and a functional material such as oil may be employed as the core solution. In this case, the functional material may be a drug, a conductive material containing silver (Ag) or carbon-based particles, antibacterial deodorant material, fragrance microcapsules, electromagnetic wave shielding material, ultraviolet curing material, oil and the like.

The solution stored in the syringe 108 is transferred to the spinning nozzle unit 120. To this end, the solution transfer pump 100 is provided with a motor unit 103 consisting of a stepping motor or a servo motor to maintain a constant amount of the transport of the solution.

The motor unit 103 is attached to the motor mounting block 104 and transmits power to the screw 105 through a predetermined coupling. In this case, an insulating coupling is disposed between the motor shaft and the screw 105 so that a high voltage leakage through the screw 105 is blocked. The motor unit 103 may be a stepping motor or a servo motor, and it is more preferable that a stepping motor is employed for fine movement. The encoder 102 is attached to the rear of the motor unit 103 to detect the rotation of the motor. When the rotation of the screw 105 is stopped, for example, for 1 to 2 seconds, the encoder 102 detects the rotation of the motor unit 103 to stop the operation of the motor unit 103 while the motor unit 103 according to the overload. To prevent overheating.

When the motor unit 103 of the solution transfer pump 100 is driven, the pusher block 106 attached to the screw 105 pushes the plunger 107 of the syringe 108 to discharge the solution in the barrel of the syringe 108. Transfer to section 120.

The pusher block 106 for solution transfer is fastened to the screw 105, and when the screw 105 is rotated by the driving of the motor unit 103, the pusher block 106 moves forward or backward along the guide rod. The guide rod may be disposed alone or both around the screw 105. The pusher block 106 includes a nut (not shown) in the center to move as the screw 105 rotates. The nut is configured with a spring on one side of the nut so as to be coupled to or detached from the screw 105, and on the other hand a cam rotating body is assembled. The cam rotator is rotated so that the nut is coupled to the screw 105 so that the pusher block 106 is advanced. When the nut is separated from the screw 105, the pusher block 106 is idle even if the screw 105 rotates. When the pusher block 106 advances, the plunger 107 of the syringe 108 moves forward. The lead of the screw 105 is 0.5 to 2 mm, preferably 1 mm. As for the moving speed of the pusher block 106 according to the rotation of the screw 105, the minimum speed is preferably 1 μm / hour to 100 μm / hour, and the maximum speed is 1 cm / minute to 20 cm / minute. The pusher block 106 may be installed and moved in the linear block instead of the guide rod.

Syringe holder 109 for fixing the syringe 108 is preferably made of an insulating material of acetal or polyethyl ketone (PEEK) to block the current flowing to the outside of the syringe (108).

The high voltage providing unit 110 applies a high voltage to the spinning nozzle unit 120 to charge the solution by applying a high voltage to the solution. The high voltage providing unit 110 is a device for providing a DC power supply, the DC power supply is supplied to the solution through contact with the radiation nozzle unit 120. The direct current voltage applied to the spinning nozzle unit 120 is 0.01 kV / cm to 10 kV / cm between the nozzle and the integrated unit 140. Preferred voltage strengths are 1 kV to 50 kV at a distance of 1 cm to 30 cm between the nozzle (tip of hollow tube needle 122) and the integrator 140. In the near field electrospinning, the distance is preferably 0.1 cm to 2 cm, and the applied voltage is preferably 0.1 kV / cm to 1.5 kV / cm. The high voltage intensity may be appropriately set according to the manufacture of ultrafine fibers or nanofibers, the type of the polymer, the viscosity of the polymer, the characteristics of the nozzle, and the shape of the disc formed from the charged liquid discharged through the nozzle.

The high voltage generated by the high voltage providing unit 110 is applied to the nozzle through the metal tube of the high voltage cable 190 connected to the radiation nozzle unit 120.

The spinning nozzle unit 120 receives at least one hollow tube needle 122 that receives a solution from the solution transfer pump 100 and discharges it in the form of a filament, and a nozzle holder 101 on which the hollow tube needle 122 may be seated. It includes. The hollow tube needle 122 is preferably an inner diameter of 0.01mm ~ 2mm, an outer diameter of 0.02mm ~ 3mm, a length of 2mm ~ 100mm.

The radiation nozzle unit 120 is connected to a high voltage cable 190 made of a metal tube with a tip portion that contacts the nozzle body to apply a high voltage. The metal tube allows high voltage to be applied to the solution through contact with the nozzle. The material of the metal tube is preferably stainless steel (SUS), copper or brass. In the case of corrosive solutions, metal tubes made of SUS are more suitable.

The support plate or the support case located at the rear of the solution transfer pump 100 is preferably made of an insulating material of metal or PEEK material. In addition, the portion in which the syringe holder 109 for holding the syringe 108 is installed should be made of an insulating material, or an insulating material cover, or coated with an insulating material. Insulation cover or coating is preferably Teflon, PEEK or silicone rubber insulation.

Syringe holder 109 is preferably made of an insulating material of polyethyl ether ketone (PEEK) or acetal to block the current flowing to the outside of the reservoir.

The cylindrical metal guide 116 and the strip-shaped metal guide 114 disposed below the spinneret unit 120 as the charge liquid control means stabilize the droplets of the charged solution and control the direction of the charged filaments generated from the droplets. Play a role. The high voltage applied to the charging liquid control means may be supplied from the same voltage source as the high voltage supplied to the spinning nozzle unit 120 for solution charging. Alternatively, the high voltage may be supplied separately. In addition, the high voltage supplied to the cylindrical metal guide 116 and the strip-shaped metal guide 114 for the control of the chargeable liquid may be applied with the same volts (V) value, and separately supplied with different voltages (V). ) Value can be added.

The cylindrical metal guide 116 acts to stabilize the droplets of the charged solution to prevent shaking. In order to more effectively prevent the droplets of the charged solution from shaking, the lower end of the cylindrical metal guide 116 is preferably disposed 1 to 5 mm higher than the tip of the hollow tube needle 122. The cylindrical metal guide 116 is disposed so that the hollow tube needle 122 coupled to the syringe 108 is located at the center, and is positioned higher than the hollow tube needle 122 such that the hollow tube needle 122 is substantially downward. It is arranged to protrude.

As shown in FIG. 4, the cylindrical metal guide 116 is fitted to the nozzle holder 101 to be fastened to the metal ring 113 positioned on the nozzle holder 101. The metal ring 113 is coupled to the lower portion of the syringe tip holder 112, and the tip is electrically contacted and connected to the high voltage cable 190 made of a metal tube. The inner diameter of the cylindrical metal guide 116 is 3-10 mm, outer diameter 4-15 mm. More preferable inner diameters are 4-8 mm and outer diameters 6-12 mm.

Outside of the cylindrical metal guide 116, it is preferable to arrange a guide cap 117 of an insulating material such as polyethyl ether ketone (PEEK) in order to prevent high exposure of the external voltage.

The strip-shaped metal guides 114 are arranged in plural to extend outwardly from the cylindrical metal guides 116. The strip-shaped metal guide 114 preferably consists of a metal plate in the form of one to four strips, that is, a relatively narrow and long shape. The strip metal guide 114 is coupled to the cylindrical metal guide 116 and is disposed to extend outwardly of the cylindrical metal guide 116. The strip metal guide 114 may be attached to and fixed to the disc-shaped support plate 115. When a plurality of strip-shaped metal guides 114 are installed, the plurality of strip-shaped metal guides 114 may be disposed coplanar with each other at the bottom of the support plate 115, alternatively downward from the support plate 115. As a result, they may be arranged so as to have different heights, and thus more directionally control the spinning filament.

The strip metal guide 114 is rotatably installed around the cylindrical metal guide 116 to adjust the direction control function for the spinning filament. At this time, the plurality of strip-shaped metal guides 114 are rotated independently or rotated integrally with each other to adjust the installation position. The strip-shaped metal guide 114 is rotated about the cylindrical metal guide 116 to adjust the installation position to control the direction of the spinning filament discharged from the hollow tube needle 122 in one to four combinations. The strip-shaped metal guide 114 may be coupled to the cylindrical metal guide 116 and rotate integrally. The strip metal guide 114 has a width of 2 to 5 mm, a length of 10 to 50 mm, and a thickness of 0.1 to 2 mm. It is preferable that materials are SUS and aluminum.

When a plurality of strip-shaped metal guides 114 are configured, they may be arranged radially at predetermined intervals and may be integrated as a whole. In this case, a fastening hole 114a having a thread formed in the inner wall is provided at the center thereof, and the cylindrical metal guide 116 is preferably screwed together. The cylindrical metal guide 116 is fitted into the fastening hole 114a and passes through the central hole 115a provided in the center of the support plate 115 to be mounted to the nozzle holder 101. The upper portion of the cylindrical metal guide 116 penetrates through the nozzle holder 101 and is engaged with the metal ring 113 positioned on the upper portion of the nozzle holder 101.

Solution transfer pump 100 is provided in accordance with the present invention is mounted in a plurality of predetermined intervals mounted on the pusher block 106 'fastened to a screw connected to the shaft of the motor unit 103' is composed of a multi-channel cartridge type Can be. In this case, as shown in FIG. 5, the cylindrical metal guide 116 and the strip-shaped metal guides 214 and 215 are separately disposed around each of the hollow tube needles 122 forming the multichannel.

The strip-shaped metal guides 214 and 215 are formed of a first strip-shaped metal guide 214 extending in a direction perpendicular to the nozzle array direction (X-axis direction), and positioned at both ends of the multiple channels and parallel to the nozzle array direction (Y). A second strip-shaped metal guide 215 including a portion extending in an axial direction). Here, the second strip-shaped metal guides 215 located at both ends of the multichannel have a direction control function for suppressing the spread of the filament discharged from the hollow tube needle 122 in the outward direction. More preferably, The second strip metal guide 215 can more effectively suppress the radial filaments from spreading outward when a portion of the second strip-shaped metal guide 215 extends downwardly (Z-axis direction).

As a high voltage applying means to the nozzles of the multi-channel, a metal tube or a metal rod of the high voltage cable 190 is in contact with a predetermined nozzle hub installed in the syringe holder 118 to apply high voltage. When the filling amount of the syringe 108 of the multiplely mounted nozzles is different, the plunger 107 does not touch the pusher block 106 'and cannot be pushed out at the same time, so that the pusher block 106' has a distance adjusting screw plate ( 119 is preferably installed to adjust the distance to the plunger 107 to transfer the solution.

All the nozzles that make up the multichannel are collectively held by a single member of the nozzle holder 118 to maintain a parallel arrangement.

The solution transfer pump 100 provided in accordance with the present invention is mounted in a dual type on the pusher block 106 'fastened to a screw connected to the shaft of the motor portion 103', and is transformed into a two-channel type of cartridge type. It is also possible. As shown in FIG. 6, a cylindrical metal guide 116 is disposed around each of the hollow tube needles 122 forming two channels. At the periphery of the cylindrical metal guide 116, a first strip metal guide 214 is disposed extending in a direction perpendicular to the nozzle arrangement direction (X-axis direction) to control the direction of the charged filament discharged from the nozzle tip. . In addition, a second strip metal guide 215 including a portion extending in a direction parallel to the nozzle arrangement direction (Y-axis direction) is disposed. Here, the second strip-shaped metal guide 215 serves as a direction control function for suppressing the spread of the spinning filaments discharged from the hollow tube needle 122 in an outward direction, and part of the second strip metal guide 215 is vertically bent downward (Z-axis direction). It can be more effectively suppressed from spreading out the spinning filaments when extending to.

2 channel type Installation of the nozzle holder 101 forms a groove 118a at the lower end of the syringe holder 118 that holds the syringe 108, and the nozzle holder 101 is grooved 118a of the syringe holder 118 from the side surface. A slide method can be employed.

The accumulation unit 140 is disposed below the spinning nozzle unit 120 to collect the charged filaments. The accumulator 140 may be configured as a flat plate, a conveyor, a roll having a diameter of 5 mm to 50 mm, a conveyor having a plurality of rods having an outer diameter of 1 mm to 5 mm, or a combination thereof. It is also possible to add a drum-shaped rotating body 160 for the collection of charged filaments.

For a continuous process, a roller integrated part or a rod integrated part consisting of a plurality is preferable. The integrated unit 140 is connected to ground or connected to a negative (-) DC voltage. When the ground is connected to the integrated unit 140, an electric field is formed between the nozzle unit and the integrated unit 140, thereby creating an electrospinning environment.

The robot driving units 130 and 131 repeatedly reciprocate in the horizontal or vertical direction of the accumulator 140 so that the microfibers radiated to the accumulator 140 of a predetermined size may be uniformly integrated. The front end of the robot drive unit (130,131) is preferably provided with an angle adjusting unit 180 for adjusting the radiation angle in order to implement vertical radiation or horizontal radiation.

The control unit 111 includes a display screen 111a and a number and function input button 111b. The display screen (111a) is the start and end points of the X axis and Y axis for the robot drive unit (130,131), the robot drive speed, the rotating body speed, the discharge progress during the driving of the solution supply, the total discharge amount, flow rate, syringe diameter, Syringe capacity is indicated. Number and function input button 111b can input the X-axis line number and the movement distance between Y-axis step of the robot drive unit 130,131, the motor power on and off button of the fluid supply unit, the flow control button, flow control restart Button, a jog button for quickly driving the motor at a set speed, and a previous step moving button. By pressing the flow control button, the total discharge volume of the solution, flow control unit selection, flow control amount, syringe selection by manufacturer and syringe capacity of the selected manufacturer can be selected, or the internal diameter of the syringe can be directly inputted. (nℓ) / minute or microliter (μl) / minute or milliliter (mℓ) / hour (hr), and configured to select whether or not to use the encoder 102 function. ) If the problem occurs, it is configured to stop running the function so that only the motor can continue to run.

The electrospinning apparatus according to the present invention may include a high voltage generator capable of applying a negative polarity to the integrated unit 140 instead of the ground. In addition, at the end of the nozzle may be included in the imaging system that can be stored in real time by monitoring the radiation state of the Taylor cone formed from the charge solution in a video or image.

In order to produce the nanofibers by applying the present invention, the discharge amount of the solution is preferably set to 0.05 μl / min to 500 μl / min per nozzle hole. More preferably, the discharge amount of the solution is 0.2 µl / min to 50 µl / min.

Using the electrospinning apparatus according to the present invention, the Taylor cone formed at the nozzle end maintains a stable state while forming a jet in the longitudinal direction. Taylor cones and jets remain stable, without biasing in either direction at the nozzle tip, even in high-voltage environments above 10 kV. The jet of the charged filament may produce a microfiber on a substrate such as a metal plate, a film, a fiber fabric, a fabric, a nonwoven fabric, a paper, a metal plate, a glass plate, a ceramic plate, and the like. In addition, the jet is made of micro to nano-sized microfibers, while the jet elongated at a higher high voltage undergoes severe fluctuations and solvent volatilization from a specific point. The microfibers produced are stacked on a grounded integrated plate and made into a membrane.

The electrospinning apparatus for microfiber fabrication of the present invention is utilized in the fabrication of microporous membranes, hollow nanofibers, cell culture scaffolds, microfiber constituent circuits, including nanofiber webs.

Experimental Example

In the experimental example, the electrospinning apparatus shown in FIG. 1 was used.

The spinning solution is a transparent solution made of PVDF [(poly) vinylidenefluoride, Kynar 2801 by Arkema] in a mixed solvent of acetone: dimethylacetamide (DMAc) 7: 3 with a solution concentration of 17% by weight. The spinning solution is equipped with a plunger-type plunger 107, and the solution outlet part is contained in a syringe 108 having a volume of 10 ml having a luerlock structure, and a hollow needle (at the outlet of the syringe 108). 122) was immediately connected to the solution transfer pump (100).

At this time, the radiation nozzle unit 120 mounted on the syringe 108 is in contact with the high voltage applying metal tube configured in the nozzle holder 101 to apply a high voltage. The nozzle is located at the center of the cylindrical metal guide 116 and the nozzle tip is located 2 mm longer than the bottom of the cylindrical metal guide 116. The strip-shaped metal guide 114 was installed around the cylindrical metal guide 116. Electrospinning was performed by driving the motor unit 103 in a state where a high voltage is applied. High voltage intensity was tested at 12.8kV respectively. The discharge amount of the solution was 25 µl / min, and the integrated part used a flat plate SUS metal plate. The distance between the nozzle tip and the SUS plate is 125 mm. Nanofibers were integrated into SUS integrated plates.

As a result, in the case of using the cylindrical metal guide 116 and the strip-shaped metal guide 114, it showed a stable spinning state at the nozzle tip, it was possible to uniformly receive nanofibers in a limited area. However, the cylindrical metal guide 116 and the strip-shaped metal guide 114 When not used, the radial direction was deflected from the nozzle tip to one side and could not be integrated properly into the desired portion of the integrated plate.

Therefore, the cylindrical metal guide 116 and the strip-shaped metal guide 114 to which high voltage is applied are When installed, it can be seen that the droplets formed on the nozzle tip can be stabilized.

Although the present invention has been described above by means of limited embodiments and drawings, the present invention is not limited thereto and will be described below by the person skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims.

100: solution transfer pump 101: nozzle holder
102: encoder 103,103 ': motor portion
104: motor mounting block 105: screw
106,106 ': Pusher block 107: Plunger
108: syringe 109,118: syringe holder
110: high voltage providing unit 111: control unit
112: syringe tip holder 113: metal ring
114: strip-shaped metal guide 115: support plate
116: cylindrical metal guide 117: guide cap
119: distance adjustment screw plate 120: spinning nozzle
122: hollow tube needle 130,131: robot drive unit
140: integrated unit 160: drum-type rotating body
180: angle adjuster 190: high voltage cable

Claims (12)

A high voltage providing unit for applying a high voltage to the spinning nozzle to charge a solution in which the polymer material is dissolved;
A spinning nozzle unit having at least one hollow tube needle configured to receive a charged solution and discharge the same in a filament form;
A cylindrical metal guide disposed at a lower end of the spinneret part to surround the hollow tube needle and to which a high voltage is applied to control droplet stability of the charged solution; And
Electrospinning apparatus for microfiber manufacturing, characterized in that it comprises a; is disposed below the spinning nozzle unit to collect the charged filament. The method of claim 1,
The cylindrical metal guide is an electrospinning apparatus for producing ultrafine fibers, characterized in that the lower end is disposed 1 ~ 5mm higher than the tip of the hollow tube needle. The method of claim 2,
An electrospinning apparatus for microfiber manufacturing, characterized in that it further comprises a strip-shaped metal guide arranged in a plurality of radially arranged strip-shaped metal plate extending in a direction perpendicular to the nozzle array direction around the cylindrical metal guide. The method of claim 3, wherein
An electrospinning apparatus for producing ultrafine fibers, characterized in that the plurality of metal plates are arranged on the same plane. The method of claim 3, wherein
An electrospinning apparatus for microfiber production, characterized in that the plurality of metal plates are arranged to be shifted so as to have a different height. The method according to claim 4 or 5,
The strip-shaped metal guide is an electrospinning apparatus for producing a microfiber, characterized in that rotatably installed around the cylindrical metal guide. In the solution transfer pump of the electrospinning apparatus for the production of ultrafine fibers,
A spinning nozzle unit having at least one hollow tube needle configured to receive a charged solution and discharge the same in a filament form; And
Solution transfer pump of the electrospinning apparatus for microfiber manufacturing, characterized in that it comprises a cylindrical metal guide is arranged to surround the hollow tube needle at the bottom of the spinning nozzle portion is applied a high voltage to control the droplet stability of the charged solution. The method of claim 7, wherein
The cylindrical metal guide is a lower end of the solution transfer pump of the electrospinning apparatus for microfiber manufacturing, characterized in that disposed 1 ~ 5mm higher than the tip of the hollow tube needle. The method of claim 8,
Solution transport of the microspun fiber electrospinning apparatus further comprising a strip-shaped metal guide arranged in a plurality of radially arranged strip-shaped metal plate extending in a direction perpendicular to the nozzle array direction around the cylindrical metal guide Pump. The method of claim 9,
Solution transfer pump of the electrospinning apparatus for microfiber production, characterized in that the plurality of metal plates are arranged on the same plane. The method of claim 9,
Solution transfer pump of the electrospinning apparatus for microfiber production, characterized in that the plurality of metal plates are arranged to be shifted so as to have a different height. The method of claim 10 or 11,
The strip-type metal guide is a solution transfer pump of the electrospinning apparatus for microfiber manufacturing, characterized in that rotatably installed around the cylindrical metal guide.

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