KR20090055934A - Nozzle block for preventing nozzles from getting blocked and polluted and bottom-up electrospinning device with the same - Google Patents

Abstract

A nozzle block and a bottom-up electrospinning apparatus including the same are provided to prevent clogging or contamination phenomenon even though a nanofiber manufacturing process is interrupted. A nozzle block(100) preventing clogging and contamination of a nozzle comprises the followings: a spinning solution inflow plate(110) in which a spinning solution inlet hole(112) is formed; a watertight spacer(130) preventing leakage of the spinning solution adopted to space storing the spinning solution; an anti-caking solution receiving part(150) attached on an upper side of the water-tightly spacer with an opened state of the upper side. A spray nozzle is mounted on the bottom of the anti-caking solution receiving part.

Description

Nozzle block for preventing nozzles from getting blocked and polluted and Bottom-up electrospinning device with the same}

The present invention relates to a nozzle block for preventing clogging and contamination of the nozzle, and more particularly, the nozzle for discharging the spinning solution when the nanofiber manufacturing process by the electrospinning method is interrupted for a short time is blocked by the solidification of the polymer material. The present invention relates to a nozzle block capable of preventing contamination caused by foreign matter in the air. The present invention also relates to a bottom-up electrospinning apparatus having the nozzle block.

Nanofibers, ranging in diameter from tens to hundreds of nanometers (one nanometer = one billionth of a meter), are much thinner and lighter than paper, easily absorb sweat, and do not penetrate foreign materials such as bacteria. . The web composed of such nanofibers is a membrane-type material having a porosity and is very usefully used in various fields such as various filters, wound dressings, artificial supports, etc., and its application area is gradually expanded.

As the field in which nanofibers are used is gradually expanded, various methods for manufacturing nanofibers have been developed and used, the most representative of which is electrospinning. Electrospinning (Electrospinning) is a technique for producing fine-diameter fibers by spinning a polymer solution in a charged state, recently used as a method for producing nanometer-class fibers has been actively researched about this .

The electrospinning method is typically implemented by an electrospinning apparatus. The electrospinning device is a top-down electrospinning device in which the collector is located under the injection nozzle. The collector is divided into a bottom-up electrospinning apparatus located on top of the spray nozzle. However, according to the top-down electrospinning apparatus, the radiating liquid is continuously supplied to the nozzles to which the high voltage is applied, so that the electric force effect imparted is lowered. Therefore, a bottom-up electrospinning apparatus for solving such a problem is gradually developed and used.

Korean Patent No. 0562006 discloses a conventional bottom-up electrospinning apparatus. Hereinafter, the bottom-up electrospinning apparatus will be described in detail with reference to FIG. 1. 1 is a conceptual diagram illustrating a bottom-up electrospinning device disclosed in the Korean patent.

The bottom-up electrospinning device is a spinning solution main tank (1) for storing spinning solution, a metering pump (2) for quantitative supply of spinning solution, a nozzle block (4) in which a plurality of nozzles for discharging spinning solution are arranged; A nozzle 5 installed in the nozzle block 4, a collector 7 for integrating fibers 6 radiated from the nozzle block 4, and for applying a voltage between the nozzle block 4 and the collector 7 And a voltage generator 9. The outlet of the nozzle 5 is formed in the upper direction, the collector 7 is located above the nozzle block (4).

The nozzle block 4 is connected to a nozzle plate 4e in which the nozzles 5 are arranged, a nozzle outer diameter hole 4b surrounding the nozzle 5, and a nozzle outer diameter hole 4b, and directly above the nozzle plate 4e. And a spinning solution temporary supply plate 4d positioned at the top, and a spinning solution main supply plate 4f located directly below the nozzle plate 4e. The nozzle outer diameter hole (4b) is installed for the purpose of recovering the spinning solution overflows without fiberization at the outlet of the nozzle (5), the spinning solution recovered by the nozzle outer diameter hole (4b) is the temporary supply plate (4d) To be collected. The spinning solution collected by the temporary supply plate 4d is forcibly transferred to the main tank 1 by the spinning solution discharging device 12. The main supply plate (4f) serves to store the spinning solution flowing into the spinning block (4) to supply to the nozzle (5).

According to the bottom-up electrospinning apparatus described above, the spinning solution discharging device 12 recovers only the spinning solution collected in the temporary supply plate 4d, but not the spinning solution contained in the main supply plate 4f. Therefore, when the nanofiber manufacturing process is interrupted for a while, the nozzle 5 is exposed to the air with the remaining spinning solution still contained therein. However, in this case, first, the solvent 5 is blocked because the solvent contained in the spinning solution is evaporated and the polymer material dissolved in the solvent is solidified inside the nozzle 5. The nozzle 5 is contaminated by foreign matter. As such, when the nozzle 5 is blocked or contaminated, the nozzle 5 needs to be replaced, so that a continuous regeneration process is impossible, and a lot of labor and cost are required for the replacement of the nozzle 5.

The present invention has been made to solve the above problems, an object of the present invention is to provide a nozzle block and a bottom-up electrospinning device equipped with the same to prevent the nozzle clogging or contamination even if the nanofiber manufacturing process is interrupted for a while. I'm taking it.

In order to achieve the above object, the present invention, the spinning solution inlet plate for forming a spinning solution inlet for the spinning solution is introduced; The upper and lower surfaces are attached to the upper surface of the spinning solution inlet plate in an open form to form a space for temporarily receiving the spinning solution introduced through the spinning solution inlet, and to prevent leakage of the spinning solution contained in the space. Watertight spacers; And an anti-solidification solution accommodating part attached to an upper surface of the watertight spacer in an open form on the upper surface thereof, wherein a spray nozzle for discharging the spinning solution contained in the space is mounted on the bottom surface of the anti-solidification solution accommodating part. When the operation of spraying the spinning solution from the spray nozzle is stopped, the spraying nozzle may be solidified so as to completely prevent the solvent contained in the spinning solution from evaporating through the end of the spray nozzle. When the anti-solidification solution is supplied to the anti-solidification solution accommodating part and the operation of spraying the spinning solution from the injection nozzle is resumed, the anti-solidification solution is recovered from the anti-solidification solution accommodating part. Provide a nozzle block to prevent contamination.

Preferably, four sides forming the anti-solidification solution accommodating part are formed of an electrical insulator. In this case, the electrical interaction between the solidification solution receiving portion and the spinning solution sprayed from the spray nozzle in a charged state can be prevented.

Preferably, the supply and recovery of the anti-solidification solution is made through the anti-solidification solution inlet hole formed on the bottom surface of the anti-solidification solution receiving portion. At this time, the anti-solidification solution inlet is connected to the anti-solidification solution storage tank for storing the anti-solidification solution by a pipe, the anti-solidification solution is supplied to the anti-solidification solution receiving portion or the anti-solidification solution receiving portion on the pipe It is preferable to be equipped with a reversible pump for recovering from the.

Preferably, the anti-solidification solution includes a component capable of dissolving the polymer material contained in the spinning solution. In this case, not only can the evaporation of the solvent contained in the spinning solution be prevented, but also the solidification prevention solution can dissolve the polymer material which may have already been solidified, thereby more reliably preventing the injection nozzle from clogging. Can be.

Preferably, when the operation of spraying the spinning solution from the spray nozzle is stopped, the spinning solution is recovered from the spray nozzle. By recovering the spinning solution from the spray nozzle, the phenomenon in which the polymer material is solidified in the spray nozzle may be blocked.

Preferably, the nozzle block further comprises a multi-purpose union connecting the insulating hose extending from the spinning solution inlet hole and the insulating hose extending from the spinning solution storage tank for storing the spinning solution, The high voltage required for the injection is applied between the multi-purpose union and the collector located above the injection nozzle. Thus, by connecting one of the two electrodes for generating a high voltage to the coffee shop union located outside of the nozzle block can be very easily installed.

The present invention also provides a bottom-up electrospinning device having a nozzle block as described above.

According to the present invention, first, the nanofiber manufacturing process can be continuously regenerated, and second, replacement of the nozzles is possible because the nanofiber manufacturing process can prevent the nozzle from being clogged or contaminated even if it is temporarily interrupted. The effect is that the labor and cost can be greatly reduced compared to the conventional.

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

Figure 2 is an exploded perspective view showing an embodiment of a nozzle block capable of preventing clogging and contamination of the nozzle according to the present invention, Figure 3 is an embodiment of a bottom-up electrospinning device equipped with the nozzle block of FIG. The conceptual diagram shown.

The nozzle block 100 according to the present invention includes a spinning solution inlet plate 110, a watertight spacer 130, and a solidification solution receiving portion 150.

The spinning solution inlet plate 110 is formed with a spinning solution inlet 112 for introducing the spinning solution stored in the spinning solution storage tank 210 (see Figure 3). 2, the number of the spinning solution inlet 112 is shown as two, but may be formed less or more than this. The spinning solution inlet 112 is connected to the insulating hose 114, the insulating hose 114 is shown as a three-way union 116 (multi-way union in Figure 2 and 3) formed of an electrically conductive metal It is connected to In addition, the coffee shop union 116 is also connected to the insulating hose 118 extending from the spinning solution storage tank 210. Meanwhile, bolt fastening holes 120 are formed at three sides of the spinning solution inlet plate 110.

The watertight spacer 130 is formed to have an open top and bottom surfaces and is attached to the top surface of the spinning solution inlet plate 110. The watertight spacer 130 has a space 132 to temporarily receive the spinning solution introduced into the spinning solution inlet 112 together with the spinning solution inlet plate 110 and the solidification solution receiving portion 150. To form. The watertight spacer 130 is preferably formed of a material having a very good watertight function such as rubber in order to prevent leakage of the spinning solution contained in the space 132 to the outside. Meanwhile, bolt fastening holes 134 corresponding to the bolt fastening holes 120 are formed at three sides of the watertight spacer 130.

The anti-solidification solution accommodating part 150 is attached to an upper surface of the watertight spacer 130 to receive the anti-solidification solution supplied from the anti-solidification solution storage tank 169. As described above in the background art, when the operation of spraying the spinning solution from the spray nozzle 102 is stopped, the solvent contained in the spinning solution evaporates and the polymer material dissolved in the solvent is injected into the spray nozzle. 102 will be solidified inside. In order to prevent such solidification, when the operation of spraying the spinning solution from the injection nozzle 102 is stopped, the anti-solidification solution is solidified so that the injection nozzle 102 can be completely immersed in the anti-solidification solution. Prohibited solution is supplied to the receiving portion 150. However, when the operation of spraying the spinning solution from the spray nozzle 102 is resumed, the anti-solidification solution may be sprayed from the spray nozzle 102 so that the anti-solidification solution may contain the solidification prevention solution accommodating part ( 150). Hereinafter, the specific configuration required to perform this process will be described in detail.

The anti-solidification solution accommodating part 150 includes a bottom plate 160 and a side plate 170.

The bottom plate 160 is formed longer than the watertight spacer 130 and the spinning solution inlet plate 110 by a predetermined length, and is attached to the top surface of the watertight spacer 130. Therefore, when the bottom plate 160 is attached to the top surface of the watertight spacer 130, the bottom plate 160 partially protrudes from the watertight spacer 130 and the spinning solution inlet plate 110 to one side (Fig. 3). The bottom plate 160 is provided with a nozzle fastening hole 162 for coupling the injection nozzle 102. The nozzle fastening hole 162 is formed to communicate with the space 132 so that the spinning solution accommodated in the space 132 flows into the injection nozzle 102 and is located within the boundary of the space 132. It is formed to.

In addition, at one side of the bottom plate 160, specifically, the portion of the watertight spacer 130 and the spinning solution inlet plate 110 protrudes from the anti-solidification solution inlet hole 164 is formed, the anti-solidification solution The inlet hole 164 is connected to the anti-solidification solution storage tank 169 for storing the anti-solidification solution by the pipe 166. The reversible pump 168 is installed on the pipe 166 to supply the anti-solidification solution to the anti-solidification solution accommodating part 150 or to recover it from the anti-solidification solution accommodating part 150. Meanwhile, bolt fastening holes 161 and 163 are formed at four sides of the bottom plate 160. At this time, the bolt fastening hole 161 is formed to correspond to the bolt fastening holes 120, 134 positionally.

The side plate 170 is formed in an open upper and lower surface form is attached to the bottom plate 160. The height (H) of the side plate 170 is formed longer than the length (L) of the injection nozzle (102), which is when the anti-solidification solution is supplied to the anti-solidification solution receiving portion 150 102 can be completely immersed in the anti-solidification solution. Meanwhile, bolt fastening grooves 172 and 174 are formed on the lower surface of the side plate 170. The bolt fastening groove 172 is formed in a position corresponding to the bolt fastening holes 120, 134, 161, the bolt fastening groove 174 corresponding to the bolt fastening hole 163 positionally Is formed. The side plate 170 is preferably formed of an electrical insulator. In this case, electrical interaction between the side plate 170 and the spinning solution injected from the injection nozzle 102 in a charged state can be prevented.

A solution capable of preventing evaporation of the solvent contained in the spinning solution may be used as the anti-solidification solution. However, it is preferable that a solution containing a component capable of dissolving the polymer material contained in the spinning solution is used as the anti-solidification solution. In this case, not only can the evaporation of the solvent contained in the spinning solution be prevented, but also the solidification prevention solution can dissolve the polymer material which may have already been solidified, thereby more reliably preventing the injection nozzle from clogging. Can be.

The spinning solution inlet plate 110, the watertight spacer 130, the bottom plate 160 and the side plate 170 is coupled by a bolt. Specifically, the coupling process of the spinning solution inlet plate 110, watertight spacer 130, the bottom plate 160 and the side plate 170 are sequentially positioned from below, the bolt fastening hole ( 120, 134, 161 and the bolt is inserted into the bolt fastening groove 172, the bolt fastening hole 163 and the bolt fastening groove 174 is also inserted into the bolt.

Previously, the anti-solidification solution accommodating part 150 was formed in a separate type in which the bottom plate 160 and the side plate 170 were separated. Alternatively, the anti-solidification solution accommodating part 150 was formed in the bottom plate 160. And the side plate 170 may be formed integrally formed integrally.

The bottom-up electrospinning apparatus according to the present invention includes a nozzle block 100, a spinning solution storage tank 210, a reversible pump 212, a high voltage applying device 220, and a collector 230. Since the nozzle block 100 is the same as described above, a description of the nozzle block 100 will be omitted below.

The spinning solution storage tank 210 stores the spinning solution to be injected from the spinning nozzle 102 and is connected to the coffee shop union 116 through an insulating hose 118. On the insulating hose 118, a reversible pump 212 for supplying a spinning solution from the spinning solution storage tank 210 to the space 132 or partially recovering the spinning solution contained in the space 132 is provided. Is mounted.

The reversible pump 212 partially recovers the spinning solution from the space 132 when the spinning solution is stopped from the injection nozzle 102. When the spinning solution is partially recovered, the injection nozzle 102 becomes empty. By partially recovering the spinning solution from the space 132, the phenomenon in which the polymer material dissolved in the spinning solution solidifies inside the injection nozzle 102 can be blocked.

The collector 230 integrates the nanofibers produced when the spinning solution is injected from the injection nozzle 102. The collector 230 is located above the nozzle block 100.

The high voltage applying device 220 is for generating a high voltage required for electrospinning, one of two electrodes for generating a high voltage is connected to the collector 230 and the other is connected to the coffee shop union 116 . Thus, by connecting one of the two electrodes for generating a high voltage to the coffee shop union 116 located outside the nozzle block 100, the installation of the electrode can be performed very easily. Previously, one of the electrodes was connected to the coffee shop union 116, but alternatively, one of the electrodes may be connected to the spinning solution inlet plate 110 or the bottom plate 160. In this case, the spinning solution inlet plate 110 or the bottom plate 160 is formed of a charger.

Hereinafter, an operation process of the bottom-up electrospinning apparatus will be described.

When the bottom-up electrospinning device is operated, the spinning solution is supplied from the spinning solution storage tank 210 to the coffee shop union 116 by the reversible pump 212. The spinning solution is charged while passing through the coffeehouse union 116 and then flows into the space 132, the spinning solution introduced into the space 132 is injected through the injection nozzle 102, in the process The resulting nanofibers are integrated in the collector 230.

On the other hand, if such a nanofiber manufacturing process is interrupted in the middle, the anti-solidification solution is supplied from the anti-solidification solution storage tank 169 to the anti-solidification solution receiving unit 150 by the reversible pump 168, thereby the spinning nozzle Clogging or contamination of the 102 can be prevented. At this time, the solidification solution is supplied so that the injection nozzle 102 is completely submerged, and the spinning solution is partially recovered by the reversible pump (212).

When the nanofiber manufacturing process is to be resumed in such a state, the anti-solidification solution is completely recovered from the anti-solidification solution accommodating part 150 using the reversible pump 168, and then the reversible pump 212, The high voltage applying device 220 and the collector 230 are operated.

In the above, the bottom-up electrospinning device according to the present invention has been described with reference to FIG. 3. However, FIG. 3 is only to help understanding the bottom-up electrospinning apparatus, and not to limit the bottom-up electrospinning apparatus, and the bottom-up electrospinning apparatus according to the present invention only needs to include the nozzle block according to the present invention. It may be of a different form than that shown in FIG.

1 is a conceptual diagram illustrating a conventional bottom-up electrospinning apparatus.

Figure 2 is an exploded perspective view showing an embodiment of a nozzle block that can prevent clogging and contamination of the nozzle according to the present invention.

3 is a conceptual diagram illustrating an embodiment of a bottom-up electrospinning apparatus equipped with the nozzle block of FIG. 2.

Claims (8)

A spinning solution inlet plate formed with a spinning solution inlet for the spinning solution to be introduced; The upper and lower surfaces are attached to the upper surface of the spinning solution inlet plate in an open form to form a space for temporarily receiving the spinning solution introduced through the spinning solution inlet, and to prevent leakage of the spinning solution contained in the space. Watertight spacers; And Including an upper surface of the anti-solidification solution receiving portion attached to the upper surface of the water-tight spacer in the form; The bottom surface of the solidification solution receiving portion is equipped with a spray nozzle for injecting the spinning solution contained in the space to the top, When the operation of spraying the spinning solution from the spray nozzle is stopped, the anti-solidification solution is completely locked so that the spray nozzle may be completely locked to prevent the solvent contained in the spinning solution from evaporating through the end of the spray nozzle. This solidification solution is supplied to the receiving portion, The nozzle block for preventing clogging and contamination of the nozzle, characterized in that when the operation to spray the spinning solution from the injection nozzle is resumed from the solidification prevention solution receiving portion. The method of claim 1, Four sides forming the solidification solution receiving portion is a nozzle block for preventing clogging and contamination of the nozzle, characterized in that formed of an electrical insulator. The method of claim 1, The nozzle block for preventing clogging and contamination of the nozzle, characterized in that the supply and recovery of the anti-solidification solution is made through the anti-solidification solution inlet formed in the bottom surface of the anti-solidification solution receiving portion. The method of claim 3, The anti-solidification solution inlet is connected to the anti-solidification solution storage tank for storing the anti-solidification solution by a pipe, and the anti-solidification solution is supplied to the anti-solidification solution accommodating part or recovered from the anti-solidification solution accommodating part on the pipe. Nozzle block for preventing clogging and contamination of the nozzle, characterized in that the reversible pump is mounted to. The method of claim 1, The solidification prevention solution is a nozzle block for preventing clogging and contamination of the nozzle, characterized in that it comprises a component capable of dissolving the polymer material contained in the spinning solution. The method of claim 1, The nozzle block for preventing clogging and contamination of the nozzle, characterized in that when the operation of spraying the spinning solution from the spray nozzle is stopped, the spinning solution is recovered from the spray nozzle. The method of claim 1, It further comprises a multi-function union connecting the insulating hose extending from the spinning solution inlet hole and the insulating hose extending from the spinning solution storage tank for storing the spinning solution, The high voltage required for the spraying of the spinning solution is applied between the multi-purpose union and the collector located above the injection nozzle, the nozzle block for preventing clogging and contamination of the nozzle. A bottom-up electrospinning apparatus comprising the nozzle block according to any one of claims 1 to 7.

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