KR101361503B1 - Electrospinning apparatus - Google Patents

Abstract

The present invention relates to an electrospinning apparatus, which can manufacture nanofibers for forming a nanofiber coating layer on various products.
Electrospinning apparatus of the present invention, the collector is bonded to the coating to form a coating layer on the surface; A rotating motor for rotating the collector; A nozzle for spraying a coating liquid in a collector direction to which the coating is bonded; A driving unit coupled to the collector and moving the collector in the front-rear direction with respect to the nozzle; A power supply for supplying power of different polarities to the collector and the nozzle; And a control unit.

Description

Electrospinning apparatus

The present invention relates to an electrospinning apparatus, which can manufacture nanofibers for forming a nanofiber coating layer on various products.

Recently, as the importance of nanofibers is highlighted, research and development on nanofiber production is actively progressing.

Nanofiber is a material that expresses high performance throughout the industry, and the application of nanomaterials such as filters using nonwoven fabrics, miniaturization of electronic devices, high functionalization, and biological tissues is increasing. The application of nanomaterials is gradually increasing.

The method of manufacturing such nanofibers uses the field radiation method the most.

Korean Patent Publication No. 10-2011-0037495 discloses an electrospinning apparatus capable of forming a coating layer on a medical stent.

1 is a perspective view schematically showing a conventional electrospinning apparatus.

As shown in FIG. 1, the conventional electrospinning apparatus includes a stent rotating part 10, a coating liquid spraying part 30, a left and right moving member 50, and a controller.

The stent rotating part 10 rotates the stent inserted into the blood vessel.

The stent rotating part 10 is composed of a cylindrical collector 110 extending in the left and right directions, and a drive member 130 for forward and reverse rotation of the collector 110.

The collector 110 can be manually inserted into the outer circumference of the collector 110 in a state in which the stent is in close contact with the operator.

The driving member 130 is coupled to the vertical plate 71.

The collector 110 is horizontally coupled to the drive shaft 131 of the driving member 130.

The driving member 130 rotates the collector 110 in the forward and reverse directions under the control of the control unit in a state where the stent is fitted to the outer circumference of the collector 110 while being in close contact with the operator.

The coating liquid injection unit 30 is composed of an inlet pipe 310, the distribution pipe 330 and the injection nozzle 350.

The inflow pipe 310 is in communication with the horizontal inlet pipe 311 and the horizontal inlet pipe 311, the coating liquid is introduced therein, the front axis of the horizontal inlet pipe 311 is hermetically connected to the outer peripheral edge of the central rear It is fixed and consists of a vertical inlet pipe 313 is introduced into the coating liquid passing through the interior of the horizontal inlet pipe 311.

The distribution pipe 330 is horizontally provided on the front side of the vertical inlet pipe 313 so as to communicate with the vertical inlet pipe 313 of the inlet pipe 310 passes through the interior of the vertical inlet pipe 313 Can be distributed.

The injection nozzle 350 is provided in a state extending in the front and rear direction on the front side of the distribution pipe 330 so as to communicate with the distribution pipe 330, the outer periphery of the stent is rotated forward and backward along the collector 110 Spraying the coating solution to form a coating layer of a predetermined thickness on the outer periphery of the stent.

The left and right moving members 50 move the coating liquid injection unit 30 left and right.

The control unit receives electric energy from a power supply unit to control the stent rotating unit 10 and the left and right moving members 50.

In addition, a separate power supply unit is provided to supply electrical energy to the coating liquid injection unit 30 and the collector 110 to provide an electric field around the injection nozzle 350 and the collector 110 of the coating liquid injection unit 30. Form.

The coating liquid may be more strongly adsorbed on the surface of the stent due to the electric field formed around the injection nozzle 350 and the collector 110 of the coating liquid injection unit 30.

However, such a conventional electrospinning apparatus cannot control the interval between the collector 110 and the spray nozzle 350 during the formation of the coating layer by starting the spraying of the coating liquid from the spray nozzle 350, thereby forming nano The thickness of the fiber coating layer and the size of the pores formed inside the coating layer could not be adjusted.

An object of the present invention is to provide an electrospinning apparatus capable of controlling the thickness of the nanofiber coating layer and the size of the pores by adjusting the distance between the nozzle and the collector during the formation of the coating layer.

In order to achieve the above object, the electrospinning apparatus of the present invention comprises: a collector to which a coating to form a coating layer is coupled to a surface; A rotating motor for rotating the collector; A nozzle for spraying a coating liquid in a collector direction to which the coating is bonded; A driving unit coupled to the collector and moving the collector in the front-rear direction with respect to the nozzle; A power supply for supplying power of different polarities to the collector and the nozzle; .

The driving unit includes a guide unit elongated in the front and rear direction with respect to the nozzle; One end is movably coupled to the guide portion, the other end is a support mounted to the rotary motor coupled to the collector; It is made of, the support is equipped with a magnetic force forming a magnetic field, the guide portion is mounted with a coil portion flowing current in the lateral direction of the vertical direction of the movement of the support, according to the direction of the current flowing in the coil portion The support moves forward and backward.

The driving unit includes a guide unit elongated in the front and rear direction with respect to the nozzle; A supporter having one end movably coupled to the guide part and the other end mounted on the rotary motor to which the collector is coupled; A moving motor for generating a driving force for moving the support in the front and rear directions; A power transmission member for connecting the support and the moving motor to move the support in the front and rear directions; .

A roller is mounted at one end of the support, and a guide rail is inserted into the guide part to move the roller.

The nozzle is composed of a plurality, each of the nozzles are connected in series by one wire, the power supply for supplying power to the nozzle supplies power to the plurality of nozzles through the one wire.

The electrospinning apparatus according to the present invention has the following effects.

The collector is moved back and forth with respect to the nozzle by the drive unit to adjust the distance between the nozzle and the collector during the formation of the coating layer, thereby appropriately adjusting the thickness of the coating layer and the size of the pores as necessary to allow different thicknesses and voids in one coating layer. It is possible to form a coating layer having.

In addition, the support mounted to the rotating motor coupled to the collector is moved forward and backward with respect to the nozzle along the guide portion, thereby making it easy to move the collector even while spraying the coating liquid from the nozzle.

In addition, the roller is mounted on one end of the support, and the guide rail for inserting and moving the roller is formed in the guide portion, so that the support can be easily moved.

In addition, the plurality of nozzles may be connected by one wire to reduce power loss by receiving power from the power supply.

1 is a perspective view schematically showing a conventional electrospinning apparatus,
2 is a perspective view schematically showing an electrospinning apparatus according to an embodiment of the present invention;
3 is a front view schematically showing an electrospinning apparatus according to an embodiment of the present invention,
4 is a side view schematically showing an electrospinning apparatus according to an embodiment of the present invention;

Figure 2 is a perspective view schematically showing an electrospinning apparatus according to an embodiment of the present invention, Figure 3 is a front view schematically showing an electrospinning apparatus according to an embodiment of the present invention, Figure 4 is according to an embodiment of the present invention It is a side view schematically showing the electrospinning apparatus, and the inside of the guide portion in which the guide rail is formed is shown, and the rotating motor disposed behind the collector is indicated by a dotted line.

4 is different from the driving unit in comparison with FIGS. 2 and 3.

Electrospinning apparatus according to an embodiment of the present invention as shown in Figures 2 to 4, the collector 100, the rotary motor 200, the nozzle 300, the driving unit 400 and the power supply device 500 Is done.

The collector 100 is bonded to the coating to form a coating layer on the surface.

The coating has a tube-shaped medical stent, and is coupled to the collector 100 to form a coating layer on the surface.

The rotary motor 200 rotates the collector 100.

Specifically, the rotary motor 200 is mounted to the drive unit 400 as shown in FIG. 2 and the collector 100 is coupled to rotate the collector 100 while moving by the drive unit 400.

The collector 100 may be rotated by the rotary motor 200 to uniformly form a coating layer on the entire outer circumferential surface of the coating body coupled to the collector 100.

The nozzle 300 sprays the coating solution toward the collector 100 to which the coating is coupled.

The nozzle 300 is composed of a plurality, each of the nozzles 300 is connected in series by one wire (301).

As shown in FIG. 2, the plurality of nozzles 300 may be connected in series with one wire 301 to receive power from the power supply 500, thereby reducing power loss.

The driving unit 400 is coupled to the collector 100, and moves the collector 100 in the front-rear direction with respect to the nozzle 300.

In detail, the driving part 400 includes a guide part 410 and a support 420.

The guide part 410 is formed long in the front-rear direction with respect to the nozzle 300.

As shown in FIG. 3, the guide part 410 is provided with a guide rail 411 in which a roller 421 mounted to the support 420 is inserted and moved.

In addition, the guide part 410 is equipped with a coil part (not shown) in which a current flows in a lateral direction in a vertical direction of the moving direction of the support 420.

According to the direction of the current flowing in the coil portion, the forward and backward movement direction of the support 420 along with the collector 100 is changed.

The current flowing through the coil part may be directly manipulated by an operator to control the direction or configure a separate controller to automatically control the direction of the current.

One end of the support 420 is movably coupled to the guide part 410, and the other end is mounted to the rotary motor 200 to which the collector 100 is coupled.

The roller 421 is mounted at one end of the support 420.

That is, the support 420 is mounted on the lower end of the roller 421 is coupled to the guide portion 410 so as to be movable, the upper end of the rotary motor 200 is coupled to the collector 100. .

The roller 421 is inserted into the guide rail 411 and moves forward and backward along the guide rail 411.

In addition, the support 420 is equipped with a magnetic force (not shown) to form a magnetic field.

The magnetic force unit forms a magnetic field around the coil unit, and the support 420 is moved forward or rearward by the electromagnetic force according to the direction of the current flowing in the coil unit.

As described above, the support 420 is easily mounted along the guide rail 411 in which the roller 421 is inserted because the roller 421 is mounted and movably coupled to the guide part 410. Can be.

The driving unit 400 uses the principle of a linear motor, and the above-described configuration is an embodiment for moving the collector 100 in the front-rear direction with respect to the nozzle 300 and may have various configurations and structures.

In addition, the driving unit 400 may move up and down to adjust the vertical height of the collector 100.

As such, the support 420 mounted to the rotary motor 200 to which the collector 100 is coupled moves in the front-rear direction with respect to the nozzle 300 along the guide part 410, thereby providing the nozzle 300. It is easy to move the collector 100 even while spraying the coating liquid in the).

On the other hand, although the nozzle 300 may be moved, if the nozzle 300 is moved in the middle of spraying the coating liquid from the nozzle 300, the spraying of the coating liquid becomes unstable, so that the coating layer is not uniform and the thickness of the coating layer and the coating layer. It is difficult to control the size of the voids formed in the.

Due to this problem, the supporter 420 on which the collector 100 is mounted is moved relative to the nozzle 300 so as to easily control the thickness of the coating layer and the size of the pores.

In addition, as shown in FIG. 4, the driving part 400 may include a guide part 410, a support 420, a moving motor 430, and a power transmission member 440.

The guide portion 410 is formed long in the front and rear direction with respect to the nozzle 300, the support 420 is one end is coupled to the guide portion 410 to be movable and the other end is coupled to the collector 100 Mounted to the rotary motor 200.

The difference from the driving unit 400 described above is that the support 420 is moved back and forth by the moving motor 430 and the power transmission member 440.

The moving motor 430 is mounted to the guide part 410 to generate a driving force to move the support 420 in the front and rear directions.

In addition, the power transmission member 440 connects the support 420 and the moving motor 430 to move the support 420 forward and backward by the driving force of the moving motor 430.

The power transmission member 440 may be various power transmission mechanisms such as a belt or a chain.

In this case, the motor may be controlled to determine a moving direction of the support 420 on which the collector 100 is mounted.

The power supply device 500 supplies power of different polarities to the collector 100 and the nozzle 300.

As described above, the power supply device 500 for supplying power to the nozzle 300 supplies power to the plurality of nozzles 300 through one wire 301.

This is to prevent the loss of power by supplying power to each nozzle 300 when using the composite nozzle (300).

The field emission method starts with the discovery of the electrostatic spray phenomenon in which fine filaments are released from the droplet surface by applying a high tension to water droplets hanging at the end of the capillary tube. Is used to form a phenomenon.

As described above, in the electrospinning apparatus of the present invention, the collector 100 is moved back and forth with respect to the nozzle 300 by the driving unit 400 so that the nozzle 300 and the collector 100 are formed even when the coating layer is formed. By controlling the distance between, the thickness of the coating layer and the size of the pores can be appropriately adjusted as necessary to form a coating layer having different thicknesses and pores in one coating layer.

Accordingly, the fiber structure of the inner portion and the outer portion of the coating layer can be prepared by different.

The nanofiber coating layer prepared as described above may be used more efficiently according to various applications.

The present invention is not limited to the above-described embodiment, the electrospinning apparatus can be carried out in various modifications within the scope of the technical idea of the present invention.

100: collector, 200: rotating motor, 300: nozzle, 301: electric wire, 400: driving part, 410: guide part, 411: guide rail, 420: support, 421: roller, 430: moving motor, 440: power transmission member, 500: power supply,

Claims (5)

delete A collector to which the coating to form a coating layer is bonded to the surface;
A rotating motor for rotating the collector;
A nozzle for spraying a coating liquid in a collector direction to which the coating is bonded;
A driving unit coupled to the collector and moving the collector in the front-rear direction with respect to the nozzle;
A power supply for supplying power of different polarities to the collector and the nozzle; , ≪ / RTI >
The driving unit includes:
A guide part elongated in the front-rear direction with respect to the nozzle;
One end is movably coupled to the guide portion, the other end is a support mounted to the rotary motor coupled to the collector; Lt; / RTI >
The support is equipped with a magnetic force forming a magnetic field,
The guide portion is equipped with a coil portion flowing current in the lateral direction perpendicular to the moving direction of the support,
And the support moves in the front-rear direction according to the direction of the current flowing in the coil part. A collector to which the coating to form a coating layer is bonded to the surface;
A rotating motor for rotating the collector;
A nozzle for spraying a coating liquid in a collector direction to which the coating is bonded;
A driving unit coupled to the collector and moving the collector in the front-rear direction with respect to the nozzle;
A power supply for supplying power of different polarities to the collector and the nozzle; , ≪ / RTI >
The driving unit includes:
A guide part elongated in the front-rear direction with respect to the nozzle;
A supporter having one end movably coupled to the guide part and the other end mounted on the rotary motor to which the collector is coupled;
A moving motor for generating a driving force for moving the support in the front and rear directions;
A power transmission member for connecting the support and the moving motor to move the support in the front and rear directions; Electrospinning apparatus, characterized in that consisting of. The method according to claim 2 or 3,
One end of the support is equipped with a roller,
Electrospinning apparatus, characterized in that the guide portion is formed in the guide rail for moving the roller is inserted. The method according to claim 2 or 3,
The nozzle is made of a plurality,
Each said nozzle is connected in series by one wire,
And a power supply device for supplying power to the nozzles to supply power to a plurality of nozzles through one of the wires.

Images