KR102387412B1 - An electrospinning apparatus having disc-type electrospinning members - Google Patents

Abstract

The present specification discloses an electrospinning apparatus having a disk-type spinning member. The electrospinning apparatus according to an embodiment of the present invention includes a housing 110 in which a spinning solution is accommodated; and a plurality of disk-type radiation members 120 rotatably disposed in the receiving space of the housing 110 .

Description

An electrospinning apparatus having disc-type electrospinning members

The present invention relates to an electrospinning apparatus, and more particularly, to an electrospinning apparatus having a disk-type spinning member capable of solving the problems of the conventional needle-type spinning nozzle.

Electrospinning is a technology that uses an electric field to spin a polymer raw material in the form of nanofibers with a diameter of about tens to hundreds of nanometers. is being utilized

For example, in the field of filter manufacturing, electrospinning technology is applied in a method of spinning nanofibers toward a fabric transported along a conveyor belt or spinning nanofibers toward a fabric attached to a rotationally driven cylindrical drum.

The electrospinning system for its application is provided with an electrospinning device for spinning nanofibers toward the fabric. And most electrospinning devices are provided with needle-type spinning nozzles, and the needle-type spinning nozzle means a type of spinning nanofibers through a spinning needle provided at the tip.

In the case of such a needle-type spinning nozzle, a problem in that the spinning solution injected into the spinning needle is hardened or the spinning needle is blocked by fine particles contained in the spinning solution is common. In particular, when a spinning solution containing a volatile solvent (eg, meta-aramid) is used, such a problem tends to occur.

In addition, in the case of a needle-type spinning nozzle, it is often found that the spinning process cannot be performed completely due to bending of the spinning needle due to an external force.

In addition, in the case of a needle-type spinning nozzle, when the electrospinning device is disposed to spin nanofibers in a horizontal or vertical downward direction, a portion of the spinning solution supplied to the nozzle falls down and the working space becomes dirty.

And, in the case of a needle-type spinning nozzle, when repair or replacement of the electrospinning device is required due to needle clogging or needle bending, it is difficult to carry out the work easily due to the narrow space, and it is difficult to clean a needle with an inner diameter of 1 mm or less. In the process, workers are often stabbed and injured by the spinning needle.

The present invention is an invention derived in consideration of the problems of the prior art described above, and is intended to provide a method to solve the problems of the conventional spinning means such as a needle type spinning nozzle.

As the above solution, the present invention provides a housing 110 in which the spinning solution is accommodated; and a plurality of disk-type radiation members 120 rotatably disposed in the receiving space of the housing 110;

The electrospinning apparatus may have a plurality of radiation gaps 121 in which the disk-type radiation member 120 is arranged along an edge.

In the electrospinning apparatus, the radiation gap 121 may extend a predetermined length from the edge toward the center of the disk-type radiation member 120 .

In the electrospinning apparatus, the supply hole 122 connected to the inner end of each of the radiation gaps 121 may be formed in the disk-type radiation member 120 .

In the electrospinning apparatus, the radiation gap 121 and the supply hole 122 may be opened toward both sides of the disk-type radiation member 120 .

The electrospinning device includes: a receiving part 111 in which the housing 110 receives the spinning solution; and a cover portion 115 that is detachably coupled to the upper portion of the receiving portion 111, wherein the cover portion 115 has a plurality of slits ( 116) may be formed.

As the above solution, the present invention also provides a housing 110 in which the spinning solution is accommodated; and at least one electrospinning module 130 rotatably mounted to the housing 110, wherein the electrospinning module 130 includes a shaft 140; and a plurality of disk-type radiation members 120 fitted to the shaft 140, wherein the disk-type radiation members 120 provide an electrospinning device having a plurality of radiation gaps 121 arranged along edges do.

The electrospinning apparatus may have a plurality of radiation gaps 121 in which the disk-type radiation member 120 is arranged along an edge.

The electrospinning device is the electrospinning module 130 is a plurality of ring-shaped partition 150; and a pair of nuts 161 and 162 fastened to both ends of the shaft 140 .

The electrospinning device is provided with a plurality of electrospinning modules (130A, 130B), the motor rotational force is applied to any one of the plurality of electrospinning modules (130A, 130B) to the electrospinning module (130A), the motor rotational force The gears 181 and 182 may be transmitted to the other electrospinning module 130B.

According to the electrospinning apparatus of the present invention, since the conventional needle-type spinning member is not used and a disk-type spinning member is used, a problem in which the spinning needle is blocked does not occur. Even if the spinning gap or the supply hole of the disk-type spinning member solidifies, the solid spinning solution can be easily removed because the spinning gap and the supply hole are open to both sides.

According to the electrospinning apparatus of the present invention, since a disk-type spinning member is used instead of a conventional needle-type spinning member, a problem in that the spinning needle is bent and cannot perform its function does not occur.

According to the electrospinning apparatus of the present invention, it is possible to spin nanofibers having a relatively larger diameter because a disk-type spinning member is used instead of a conventional needle-type spinning member, and a larger number of nanofibers can be spun. it is possible Specifically, the inner channel of the spinneret has a small diameter and volume. Since the spin gap according to the present invention can be formed to have a larger volume than that of the inner channel, the electrospinning device of the present invention has a larger amount per unit time. of nanofibers can be spun. Accordingly, the electrospinning apparatus of the present invention can exhibit significantly improved productivity than the prior art.

According to the electrospinning apparatus of the present invention, since a method of spinning nanofibers in an upward direction is applied, there is no problem in that a part of the spinning solution falls to the floor in the horizontal spinning method and the working space becomes dirty.

According to the electrospinning apparatus of the present invention, since assembly and disassembly are made of a simple structure, maintenance is very easy. In particular, since the electrospinning module has a structure in which assembly is completed through nut coupling, assembly and disassembly processes are very simple.

According to the electrospinning apparatus of the present invention, since the plurality of disk-type spinning members are disposed in the housing filled with the spinning solution and receive the spinning solution directly therefrom, no additional spinning solution delivery means such as a spinning solution supply hose is required. Therefore, since the configuration of the electrospinning system is much simpler than that of the prior art, the system design is simple and the manufacturing cost is much reduced.

1 is a view showing an electrospinning apparatus 100 according to an embodiment of the present invention.
FIG. 2 is a partially enlarged view of the upper surface of the electrospinning apparatus 100 .
3 is a view showing the electrospinning apparatus 100 in a state in which the cover is removed.
4 is a view showing the electrospinning apparatus 100 in a state in which the cover is removed.
5 is an exploded view showing the components of the electrospinning module 150 .
6 and 7 are views showing the disk-type radiation member 120 .
8 is a view showing an example of electrospinning using the electrospinning device 100 for the fabric wound on the rotary drum.
9 is a view showing an example of electrospinning using the electrospinning apparatus 100 for the horizontally transferred fabric.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings.

An electrospinning apparatus 100 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 7 .

1 is a view showing an electrospinning apparatus 100 according to an embodiment of the present invention, FIG. 2 is a partially enlarged view of the upper surface of the electrospinning apparatus 100, and FIG. 3 is an electrospinning apparatus 100 It is a view showing the cover removed state, FIG. 4 is a view showing the electrospinning apparatus 100 in a state in which the cover is removed, FIG. 5 is a view showing the components of the electrospinning module 150 disassembled, and FIGS. 6 and 7 is a view showing a disk-type radiation member.

The electrospinning apparatus 100 of this embodiment includes a housing 110 for accommodating a spinning solution, and a plurality of disk-type spinning members 120 for spinning nanofibers formed from the spinning solution.

6 and 7, the disk-type radiation member 120 has a substantially disk shape.

A plurality of radiation gaps 121 arranged along an edge of the disk-type radiation member 120 are formed. Nanofibers are spun from this spinning gap 121 . The radiation gap 121 has a linear, narrow gap shape. In the drawings, the radiation gap 121 is illustrated as being formed along the radial direction of the disk-type radiation member 120 , but it is not limited thereto and may be formed along a direction slightly shifted with respect to the radial direction.

A supply hole 122 connected to the inner end of the radiation gap 121 is formed in the disk-type radiation member 120 . The spinning solution is filled in the supply hole 122 , and the spinning solution is supplied to the spinning gap 121 . The supply hole 122 is shown in the shape of a circular through hole, but is not limited thereto and may be formed in a shape such as an oval through hole, a square through hole, or a triangular through hole.

As described above, in this embodiment, the supply hole 122 is formed at the inner end of each of the radiation gaps 121 for the purpose of expanding the content of the spinning solution. However, it is also possible to omit the supply hole 122 in the disk-type radiation member 120 and to form only the radiation gap 121 .

6 and 7, in the present embodiment, the disk-type radiation member 120 has a plurality of triangular-shaped protrusions 125 formed along the edges, and the aforementioned radiation gaps ( 121) and the supply hole 122 are formed one by one. In an alternative embodiment, the shape of the protrusion 125 may be designed to be changed to a semicircular shape, a semi-elliptical shape, a pentagonal shape, or the like. Also, in an alternative embodiment, the disk-type radiation member 120 may be designed in a shape without protrusions. That is, the disk-type radiation member 120 may be manufactured in a circular shape in which no protrusions are formed on the edge.

A shaft insertion hole 127 is formed in the center of the disk-type radiation member 120 .

The disk-type radiation member 120 is made of a metal material having electrical conductivity.

As described above, the spinning solution is filled in the housing 110 . And as the plurality of disk-type spinning members 120 disposed in the housing 110 rotate, the spinning solution is injected into the spinning gap 121 and the supply hole 122 to become a raw material for nanofibers. This will be described again later.

1 to 4 , the housing 110 includes a receiving part 111 . The spinning solution supplied from the outside is filled in the receiving part 111 . The spinning solution is not completely filled in the accommodating part 111 , but is filled to such an extent that a portion of the disk-type spinning member 120 is submerged. A plurality of disk-type radiation members 120 are disposed in the receiving portion 111 .

As shown in FIG. 3 , the plurality of disk-type radiation members 120 are arranged in two rows, and a plurality of disk-type radiation members 120 arranged at equal intervals in each row may be included. Although the plurality of disk-type radiation members 120 are arranged in two rows in the present embodiment, the plurality of disk-type radiation members 120 may alternatively be arranged in one row or three rows. When arranged in a plurality of columns in a plurality of second and third columns, the disk-type radiation members 120 have a zigzag arrangement as shown in the figure so that the distance between the columns is minimized and mutual interference does not occur. it is preferable

As shown in FIG. 1 , a nozzle 112 is provided on one side of the receiving part 111 . And the nozzle 112 is provided with a valve 113 . The nozzle 112 is configured to supply the spinning solution to the receiving unit 111 at a certain level or to discharge the remaining spinning solution in the receiving unit 111 to the outside after work is completed and discarded. The valve 113 is opened.

1 to 4 , the housing 110 also includes a cover portion 115 .

The cover part 115 is detachably mounted to the housing 110 , and may be separated therefrom to open the receiving part 111 if necessary. For example, a user such as an administrator may separate the cover part 115 from the receiving part 111 when injecting a spinning solution into the housing 110 or repairing the electrospinning apparatus 100 to perform related work.

As shown in FIG. 4 , a plurality of slits 116 are formed in the cover part 115 . The arrangement of the plurality of slits 116 corresponds to the arrangement of the plurality of disk-type radiation members 120 . For example, when the plurality of disk-type radiation members 120 are arranged in two rows, the plurality of slits 116 are also arranged in two rows correspondingly as shown in FIG. 4 , and in this case, the slits 116 in each row are may be arranged at intervals.

As shown in FIG. 2 , in a state in which the receiving part 111 is closed by the cover part 115 , most of the plurality of disk-type radiation members 120 are disposed in the housing 110 , and a part thereof is disposed in the housing 110 . It is exposed outside through the plurality of slits 116 . For example, as shown in FIG. 2 , about five of the plurality of protrusions 125 formed on the edge of the disk-type radiation member 120 may be exposed through the slit 116 .

The width of the slit 116 is preferably designed to be slightly wider than the thickness of the disk-type radiation member 120 . Through this design, the spinning solution on both sides of the disk-type spinning member 120 can be removed by being swept away by the slit 116 . More specifically, during the electrospinning operation, it is ideal that the spinning solution is supplied only to the spinning gap 121 and the supply hole 122 of the disk-type spinning member 120 , but the spinning solution in the receiving part 111 is the disc-type spinning member. It has no choice but to be smeared on both sides of the member 120 , and in order to prevent deterioration of the electrospinning quality that may be caused by this, the spinning solution adhering to both sides of the member 120 is swept away by the slit 116 .

The cover part 115 also serves to prevent the spinning solution in the receiving part 111 from being solidified due to contact with external air by closing the receiving part 111 .

In the present embodiment, the housing 110 constitutes the accommodating part 111 and the cover part 115 , but alternatively, the housing 110 may be configured only with the accommodating part 111 without the cover part 115 .

3 to 5 , the electrospinning apparatus 100 includes at least one electrospinning module 130 .

In this embodiment, two electrospinning modules (130A, 130B) are provided, but according to the embodiment, the number of electrospinning modules may be changed to one, three, etc.

A plurality of disk-type radiation members 120 are arranged in each of the electrospinning modules 130A and 130B, and these disk-type radiation members 120 are preferably arranged at equal intervals.

In the drawings, each of the electrospinning modules (130A, 130B) has been illustrated as being provided with 14 or 15 disk-type radiation members 120, the number of disk-type radiation members provided in the electrospinning modules (130A, 130B) can be variously designed to be less or more than that.

As shown in Figure 4, the disk-type radiation members 120 provided in the two adjacent electrospinning modules (130A, 130B) are arranged to form a zigzag arrangement with each other. Thereby, it is possible to minimize the distance between the two electrospinning modules (130A, 130B) while preventing interference between the disk-type radiation members 120 provided in the other electrospinning modules (130A, 130B).

5, each electrospinning module 130 includes a shaft 140, a plurality of disk-type radiation members 120, a plurality of ring-shaped partitions 150, and a pair of nuts 161 and 162. can be configured.

In the assembly process of the electrospinning module 120, a pair of nuts 161, 161, 162) by fastening.

This assembly process is very simple, and if necessary, the electrospinning module 120 can be simply disassembled only by separating the nuts 161 and 162 . Therefore, when it is necessary to repair the electrospinning module 120, the operation can be easily performed.

The shaft 140 is made of a metal material having electrical conductivity. In addition, the ring-shaped partition 150 disposed between the disk-type radiation members 120 is also made of a metal material having electrical conductivity.

3 and 4 , the electrospinning modules 130A and 130B are rotatably mounted to the housing 110 . The rotational force of a motor (not shown) is transmitted to any one of the electrospinning modules 130A of the electrospinning modules 130A and 130B, and the rotating force is a rotating force transmitting means 181 connected between the electrospinning modules 130A and 130B. 182) is transferred to the other electrospinning module (130B).

3 and 4, the electric spinning module 130A may be provided with a belt pulley 170 for receiving the motor rotational force through the belt, and the rotational force transmitting means between the electrospinning modules 130A and 130B. For (181, 182), a pair of intermeshing gears can be used. In this case, the electrospinning modules (130A, 130B) rotate in opposite directions to each other.

If only one electrospinning module 130 is provided in the electrospinning apparatus 100, the rotational force transmitting means 181 and 182 do not need to be provided. When the three electrospinning modules 130 are provided, three gears meshed with each other may be used as the rotational force transmitting means.

The electrospinning apparatus 100 of the present invention can be used in a way that spins the nanofiber upwards.

For example, as shown in FIG. 8, the electrospinning apparatus 100 of the present invention may be used as a means for spinning nanofibers upward toward the fabric 1 wound on the rotary drum 10. In this case, a voltage is supplied between the rotating drum 10 and the radiating members 120 of the electrospinning apparatus 100 to form an electric field for electrospinning in the space therebetween.

As another example, the electrospinning apparatus 100 of the present invention may be used as a means for spinning nanofibers toward the fabric 1 that is horizontally transported along a conveyor belt (not shown) as shown in FIG. 9 . In this case, by supplying a voltage between the electrode plate 20 and the electrospinning device 100 disposed on the fabric 1, an electric field for electrospinning is formed in the space therebetween.

Referring to FIGS. 8 and 9 , the disk-type radiation member 120 is partially immersed in the spinning solution 110 in the housing 110 and partially exposed outside the housing 110 . And, the disk-type spinning member 120 is rotationally driven during the electrospinning operation. Thus, while the radiation gap 121 and the supply hole 122 of the disk-type radiation member 120 pass through the inside of the housing 110 , the radiation liquid 110 penetrates and fills it, and the radiation gap 121 . And while the supply hole 122 is exposed out of the housing 110 , the nanofiber is spun toward the fabric 1 from the spinning gap 121 .

Referring back to FIG. 3 seen earlier, during this nanofiber spinning operation, the electrospinning apparatus 100 is driven to reciprocate at a predetermined pitch along the direction of the arrow shown in FIG. 3 , that is, in the longitudinal direction of the electrospinning modules 130A and 130B. can be As such, by reciprocating the electrospinning device 100, the nanofibers spun from the spinning members 120 can be uniformly coated on the fabric, and as a result, the coating uniformity of the nanofibers is improved.

According to the electrospinning apparatus 100 of the present invention, since the disk-type spinning member 120 is used instead of the conventional needle-type spinning member, the problem that the spinning needle is blocked does not occur. A case may occur in which the spinning solution in the spinning gap 121 or the supply hole 122 of the disk-type spinning member 120 is hardened, but since the spinning gap 121 and the supply hole 122 are open to both sides, it is hardened. The spinning solution can be easily removed.

According to the electrospinning apparatus 100 of the present invention, since the disk-type spinning member 120 is used instead of the conventional needle-type spinning member, there is no problem that the spinning needle is bent and cannot perform its function.

According to the electrospinning apparatus 100 of the present invention, since the disk-type spinning member 120 is used instead of the conventional needle-type spinning member, it is possible to spin nanofibers having a relatively larger diameter as needed. It is possible to spin a larger number of nanofibers. The inner channel of the spinneret is inevitably small in diameter and volume. Since the spin gap according to the present invention can be formed to have a larger volume than that of the inner channel, the electrospinning apparatus 100 of the present invention can produce more than one per unit time. Positive nanofibers can be spun. Therefore, the electrospinning apparatus 100 of the present invention can exhibit significantly improved productivity than the prior art.

According to the electrospinning apparatus 100 of the present invention, since a method of spinning nanofibers in an upward direction is applied, there is no problem in that a part of the spinning solution falls to the floor in the horizontal spinning method and the working space becomes dirty.

According to the electrospinning apparatus 100 of the present invention, since assembly and disassembly are made of a simple structure, maintenance is very easy. In particular, since the electrospinning module 130 has a structure in which the assembly is completed through the coupling of the nuts 161 and 162, the assembly and disassembly process is very simple.

According to the electrospinning apparatus 100 of the present invention, since the plurality of disk-type spinning members 130 are disposed in the housing 110 filled with the spinning solution and receive the spinning solution directly therefrom, any additional A spinning solution delivery means is also not required. Therefore, since the configuration of the electrospinning system is much simpler than that of the prior art, the system design is simple and the manufacturing cost is much reduced.

100: electrospinning device
110: housing
111: receiving part
115: cover part
116: slit
120: disk type radiation member
121: radiation gap
122: supply hole
130, 130A, 130B: Electrospinning module
140: shaft
150: ring-shaped partition
161, 162: Nuts
170: belt pulley
181, 182: gear

Claims (10)

a housing 110 in which the spinning solution is accommodated; and
Includes; a plurality of disk-type radiation members 120 rotatably disposed in the receiving space of the housing 110;
The disk-type radiation member 120 is
a plurality of supply holes 122 filled with the spinning solution; and
It has a linear gap shape extending from the plurality of supply holes 122 to the edge of the disk-type spinning member 120 , and a plurality of spinning gaps for spinning nanofibers by receiving a spinning solution from the plurality of supply holes 122 . (121);
The supply hole 122 and the radiation gap 121 are opened toward both sides of the disk-type radiation member 120,
The housing 110 is
a receiving part 111 in which the spinning solution is accommodated; and
and a cover portion 115 that is detachably coupled to the upper portion of the receiving portion 111
A plurality of slits 116 are formed in the cover part 115 to partially expose the plurality of disk-type radiation members 120 and sweep and remove the spinning solution on both sides of the disk-type radiation member 120 .
electrospinning device.
delete delete delete delete delete a housing 110 in which the spinning solution is accommodated; and
At least one electrospinning module 130 rotatably mounted to the housing 110; includes;
The electrospinning module 130 is
shaft 140; and
Includes; a plurality of disk-type radiation members (120) fitted to the shaft (140);
The disk-type radiation member 120 is
a plurality of supply holes 122 filled with the spinning solution; and
It has a linear gap shape extending from the plurality of supply holes 122 to the edge of the disk-type spinning member 120 , and a plurality of spinning gaps for spinning nanofibers by receiving a spinning solution from the plurality of supply holes 122 . (121);
The supply hole 122 and the radiation gap 121 are opened toward both sides of the disk-type radiation member 120,
The housing 110 is
a receiving part 111 in which the spinning solution is accommodated; and
and a cover portion 115 that is detachably coupled to the upper portion of the receiving portion 111
A plurality of slits 116 are formed in the cover part 115 to partially expose the plurality of disk-type radiation members 120 and sweep and remove the spinning solution on both sides of the disk-type radiation member 120 .
electrospinning device.
delete 8. The method of claim 7,
The electrospinning module 130 is
a plurality of ring-shaped partitions 150; and
A pair of nuts (161, 162) fastened to both ends of the shaft (140); further comprising
electrospinning device.
8. The method of claim 7,
A plurality of electrospinning modules (130A, 130B) are provided,
A motor rotational force is applied to any one of the plurality of electrospinning modules 130A, 130B, and the motor rotating force is transmitted to another electrospinning module 130B through gears 181 and 182
electrospinning device.

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