JP2012167409A - Electrospinning device and apparatus for producing nanofiber - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrospinning device and an apparatus for producing nanofiber which facilitate the maintenance of a nozzle and can set a way of supplying a polymer solution in various ways.SOLUTION: An electrospinning device comprises: a nozzle block 250 on which a plurality of nozzles 240 are two-dimensionally arranged; and a polymer solution supplying device 400, and discharges the polymer solution to a long sheet to deposit a nanofiber thereon. The polymer solution supplying device 400 has polymer solution tanks 411 and 412 for storing a plurality of polymer solutions that contain a different component therein, and polymer solution circulating pipes 421 to 427 for circulating the polymer solution for each kind of the polymer solutions. The nozzle block 250 has tube bodies 271 to 277 that have one end that is a closed end and the other end that serves as a supply port of the polymer solution. Each tube body has the predetermined number of nozzles 240 installed along a longitudinal direction. In addition, polymer solution circulating pipes 421 to 427 for circulating the polymer solution are connected to each supply port of the polymer solution of each tube body.

Description

  The present invention relates to an electrospinning apparatus and a nanofiber manufacturing apparatus.

  2. Description of the Related Art Conventionally, a nanofiber manufacturing apparatus that manufactures nanofibers by performing electrospinning with an electrospinning apparatus provided along the conveying direction of a long sheet is known (for example, see Patent Document 1).

  FIG. 9 is a view for explaining a conventional nanofiber manufacturing apparatus 900. As shown in FIG. 9, the conventional nanofiber manufacturing apparatus 900 includes a transport device 910 that transports a long sheet W along a predetermined transport direction, and a long sheet W that is transported by the transport device 910. And an electrospinning device 920 that electrospins the long sheet W by discharging the solution.

  The electrospinning apparatus 920 includes a collector 930, a nozzle block 950 in which a plurality of nozzles 940 for discharging a polymer solution are two-dimensionally arranged at a predetermined arrangement pitch, and a collector 930. And a nozzle block 950 are provided with a power supply device 960 that applies a high voltage.

  In the conventional nanofiber manufacturing apparatus 900, the plurality of nozzles 940 are directly attached to the nozzle block 950, and each nozzle is supplied after the polymer solution stored in the polymer solution tank 970 flows into the nozzle block 950. 940 to be supplied.

Japanese Patent No. 4414458

  In the conventional nanofiber manufacturing apparatus 900, as described above, the plurality of nozzles 940 are directly attached to the nozzle block 950, and the polymer solution is supplied to each nozzle 940 via the nozzle block 950. It is configured as follows.

  For this reason, when repairing or replacing the nozzle 940, depending on the situation, it may be necessary to remove the entire nozzle block 950 from the electrospinning device 920, and there is a problem that maintenance is not easy, and the polymer solution There is also a problem that it is not possible to set various ways of supply.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an electrospinning apparatus and a nanofiber manufacturing apparatus that facilitate maintenance of a nozzle and can set various ways of supplying a polymer solution.

   [1] An electrospinning apparatus according to the present invention includes a collector, a nozzle block provided in a position facing the collector, and a plurality of nozzles for discharging a polymer solution two-dimensionally arranged; A long sheet that is transported in a predetermined transport direction between the collector and the nozzle, and a polymer solution supply device that supplies power to the polymer solution supply device and a power supply device that applies a high voltage between the collector and the nozzle An electrospinning apparatus for depositing nanofibers by discharging the polymer solution, wherein the polymer solution supply apparatus comprises a polymer solution tank for storing a plurality of types of polymer solutions having different components, and the plurality of types of polymer solutions. A plurality of polymer solution distribution pipes that distribute for each type of polymer solution, and the nozzle block includes A plurality of pipes arranged along the width direction of the sheet, with one end portion being a closed end and the other end portion being a polymer solution supply port along the conveying direction of the long sheet. A predetermined number of nozzles are attached to each of the plurality of tubes along the longitudinal direction of each tube, and the polymer solution supply port of each tube has The polymer solution distribution pipe for distributing the type of polymer solution allocated to the tube is connected so that the type of polymer solution allocated to the tube is supplied.

  According to the electrospinning apparatus of the present invention, the nozzles are attached to a plurality of tubes disposed inside the nozzle block. Therefore, when the nozzle is repaired or replaced, the nozzle can be repaired or replaced in units of tubes, so that the maintenance of the nozzle can be facilitated. Further, for example, the supply amount of the polymer solution is controlled for each nozzle arranged along the width direction of the long sheet, or different types of polymer solutions are used for each nozzle arranged along the width direction of the long sheet. The supply method of the polymer solution can be set in various ways.

[2] In the electrospinning apparatus of the present invention, it is preferable that each of the tubes is detachably attached to the nozzle block.
Thereby, each tubular body can be easily taken out from the nozzle block, and when repairing or replacing the nozzle, it is possible to easily repair or replace the nozzle on a tubular body basis.

   [3] In the electrospinning apparatus of the present invention, a polymer solution supply amount control valve capable of controlling a supply amount of the polymer solution for each of the tubes corresponds to the tubes in the polymer solution circulation pipe. Are preferably provided.

  By having such a configuration, it is possible to control the supply amount of the polymer solution for each tubular body. Also, for example, when the type of polymer solution is assigned to each tube, the supply amount of the polymer solution of the type assigned to each tube can be controlled for each tube. Various distributions of different polymer solutions can be set. In the present invention, “allowing control of the supply amount of the polymer solution” means that the opening amount of the polymer solution supply amount control valve can be controlled from zero to the maximum. Thereby, the supply amount of the polymer solution can be arbitrarily controlled from zero to the maximum value.

  [4] In the electrospinning apparatus of the present invention, the polymer solution distribution pipe is provided with a polymer solution supply amount control valve that can collectively control the supply amount of the polymer solution for each type of the polymer solution. It is also preferable.

  By having such a configuration, it is possible to collectively control the supply amount for each type of polymer solution, so that the distribution of different types of polymer solutions can be easily changed.

[5] In the electrospinning apparatus of the present invention, it is preferable that the polymer solution tank is individually provided for each type of the polymer solution.
With such a configuration, a plurality of types of polymer solutions can be stored for each type of polymer solution.

[6] In the electrospinning apparatus of the present invention, the polymer solution tank has an inner portion so as to form a plurality of polymer solution storage chambers capable of storing the plurality of types of polymer solutions for each type of the polymer solution. An electrospinning apparatus characterized by being divided.
Even with such a configuration, a plurality of types of polymer solutions can be stored for each type of polymer solution.

  [7] In the electrospinning apparatus of the present invention, the nozzles attached to the pipes are the pipes to which the same kind of polymer solution is assigned when the nozzle block is viewed in the transport direction. In each tube body, the rows in the conveyance direction by the nozzles attached to the body are arranged on a straight line having a predetermined angle with respect to the conveyance direction on a plane parallel to the surface of the long sheet. It is preferable that it is attached.

  By arranging the nozzles attached to the pipes in such an arrangement, the pipes to which the same kind of polymer solution is assigned to the nozzles in the longitudinal direction of each pipe (the width direction of the long sheet) Are adjacent to each other. Thereby, the nanofiber which consists of each kind of polymer solution can be uniformly deposited with respect to the elongate sheet | seat conveyed along a conveyance direction, respectively.

  [8] In the electrospinning apparatus of the present invention, the nozzle and each tube are made of a conductive member, and one of the positive electrode and the negative electrode of the power supply device is connected to the collector, and the power supply It is preferable that the other electrode of the positive electrode and the negative electrode of the device is connected to each tube body, and the side of each tube body is at a ground potential.

  In this way, since each tube body side is set to the ground potential, the components electrically connected to each tube body (for example, “the polymer solution before being ejected from the nozzle” including the nozzle block and the housing, Since all of the “polymer solution supply device for supplying the polymer solution to each tube” and the like ”are at ground potential, it is not necessary to set these components to high withstand voltage specifications. Therefore, the mechanism of the electrospinning device is not complicated due to the high voltage specifications of these components.

  The “polymer solution supply device for supplying the polymer solution to each tube” includes a polymer solution tank, a polymer solution distribution pipe, a polymer solution supply amount control valve, and the like.

  [9] The electrospinning apparatus of the present invention preferably further includes a reciprocating drive unit that reciprocates the nozzle block at a predetermined cycle along the width direction of the long sheet.

  By having such a reciprocating drive unit, the nozzle block can be reciprocated along the width direction of the long sheet. In this case, if the reciprocating motion cycle is controlled to be an appropriate cycle, the discharge position of each nozzle is prevented from overlapping the discharge positions of other nozzles as much as possible with respect to the long sheet being transported in the transport direction. be able to. Thereby, the amount of polymer fibers deposited on the long sheet W can be made uniform.

  [10] The electrospinning apparatus of the present invention preferably further includes an interval adjustment drive unit that drives the nozzle block so as to adjust the interval between the nozzle block and the collector.

  By having such an interval adjustment drive unit, the interval between the nozzle block and the collector can be adjusted. In this case, if the interval between the collector and the nozzle block is adjusted to an optimum interval before starting the electrospinning, the electrospinning can be performed in a state where the distance between the nozzle block and the collector is optimally set. it can. The interval between the collector and the nozzle block can be determined in consideration of the spinning conditions of the electrospinning apparatus, the type of polymer solution, the average diameter of the nanofibers, the thickness of the nanofiber nonwoven fabric, and the like.

  [11] The nanofiber manufacturing apparatus of the present invention includes a transport device that transports a long sheet in a predetermined transport direction, and an electrospinning device that electrospins the long sheet transported in the predetermined transport direction. The nanofiber production apparatus is characterized in that the electrospinning apparatus is the electrospinning apparatus according to any one of [1] to [10].

  According to the nanofiber production apparatus of the present invention, since the electrospinning apparatus of the present invention is provided, nanofibers having desired performance can be stably produced.

  [12] In the nanofiber manufacturing apparatus of the present invention, the transport device feeds the long sheet, transports the long sheet at a predetermined transport speed, and nanofibers are fed by the electrospinning device. A take-up roller for winding the accumulated long sheet, a take-up roller driving unit for driving the take-up roller, and provided on the supply roller side and the take-up roller side than the electrospinning device, It is preferable to have a first tension roller and a second tension roller for applying a predetermined tension to the long sheet.

  By having such a configuration, the long sheet can be conveyed with appropriate tension along the conveyance direction.

  [13] In the nanofiber manufacturing apparatus of the present invention, the first tension roller has at least one position in the vertical and horizontal directions of one end and the other end of the first tension roller. A first tension roller position adjusting mechanism that can be adjusted independently for each of the two tension rollers, wherein the second tension roller has at least one end and one end of the second tension roller in the vertical and horizontal directions. It is preferable to have a second tension roller position adjustment mechanism that allows one position to be adjusted independently for each end.

  By having such a configuration, it is possible to correct the deviation in the conveyance direction of the long sheet and to easily adjust the tension so as to obtain an appropriate tension.

  [14] In the nanofiber manufacturing apparatus of the present invention, the transport device outputs a winding amount measurement information indicating a winding amount of a long sheet on which the nanofibers are deposited on the winding roller. It is preferable to further include a measurement information output device and a conveyance speed control device that controls the winding roller driving unit based on the winding amount measurement information output from the winding amount measurement information output device.

  By adopting such a configuration, even when the winding amount of the “long sheet on which nanofibers are deposited” in the winding roller changes, the conveyance speed of the long sheet can always be kept constant.

  [15] In the nanofiber manufacturing apparatus of the present invention, the transport device is provided at a predetermined position between the electrospinning device and a take-up roller, and the long sheet on which the nanofibers are deposited It is preferable to further have a cutting device for cutting along the width direction of the sheet.

  By having such a configuration, when a predetermined amount of the “long sheet on which nanofibers are deposited” is wound up by a winding roller, the “long sheet on which nanofibers are deposited” is cut at a predetermined position. Can do. In this case, a winding roller that does not wind up the “long sheet on which nanofibers are deposited” is newly attached, and the tip of the subsequent “long sheet on which nanofibers are deposited” is attached to the winding roller. . By repeating such an operation, the “long sheet on which nanofibers are deposited” can be easily taken out for each predetermined winding amount.

  In addition, according to the nanofiber manufacturing apparatus of the present invention, high-function / high-sensitivity textiles and other clothing items, health care and skin care-related products, wiping cloths, filters and other industrial materials, secondary battery separators, capacitor separators To manufacture nanofibers that can be used for a wide variety of applications such as various catalyst carriers, electronic / mechanical materials such as various sensor materials, regenerative medical materials, biomedical materials, medical MEMS materials, biosensor materials, etc. Can do.

It is a figure shown in order to demonstrate the nanofiber manufacturing apparatus 1 which concerns on embodiment. It is an enlarged view which takes out and shows the electrospinning apparatus 200 in FIG. It is a figure shown in order to demonstrate the nozzle block 250. FIG. It is a figure which shows the arrangement | sequence of the nozzle 240 typically. FIG. 3 is a diagram for illustrating a configuration of a main control device 300. It is a figure shown in order to demonstrate the 1st modification of the polymer solution supply apparatus 400. FIG. It is a figure shown in order to demonstrate the 2nd modification of the polymer solution supply apparatus 400. FIG. It is a figure shown in order to demonstrate the 3rd modification of the polymer solution supply apparatus 400. FIG. It is a front view of the conventional nanofiber manufacturing apparatus 900.

  Hereinafter, the nanofiber manufacturing apparatus of the present invention will be described based on the embodiments shown in the drawings.

1. Electrospinning apparatus and nanofiber manufacturing apparatus according to the embodiment FIG. 1 is a diagram illustrating a nanofiber manufacturing apparatus 1 according to the embodiment. FIG. 1A is a front view of the nanofiber manufacturing apparatus 1, and FIG. 1B is a plan view of the nanofiber manufacturing apparatus 1. In addition, in FIG. 1, the component required when describing the nanofiber manufacturing apparatus 1 which concerns on embodiment is shown, and illustration of the housing | casing etc. which comprise a nanofiber manufacturing apparatus is abbreviate | omitted. Further, in FIG. 1A, some members are shown in a cross-sectional view.

FIG. 2 is an enlarged view showing the electrospinning apparatus 200 in FIG.
FIG. 3 is a view for explaining the nozzle block 250. 3A is a perspective view when the cover body 251 of the nozzle block 250 is removed, and FIG. 3B is a perspective view when the cover body 251 of the nozzle block 250 is attached. FIG. 4 is a diagram schematically showing the arrangement of the nozzles 240. FIG. 5 is a diagram for explaining the main controller 300.

  As shown in FIG. 1, the nanofiber manufacturing apparatus 1 according to the embodiment includes a transport device 100 that transports a long sheet W in a predetermined transport direction a, and a long sheet W that is transported along the transport direction a. An electrospinning apparatus 200 for electrospinning, an operation unit (to be described later) of the transport apparatus 100, and a main controller 300 for controlling each operation unit of the electrospinning apparatus 200.

  The nanofiber manufacturing apparatus 1 according to the embodiment includes a VOC processing apparatus that burns and removes volatile components generated when nanofibers are deposited on the long sheet W in addition to the above-described constituent elements, and electrospinning. When an abnormality is detected in the apparatus 200, an inert gas supply apparatus that supplies an inert gas to the electrospinning chamber 212 in the electrospinning apparatus 200 is provided, but these are not shown.

  As shown in FIG. 1, the conveyance device 100 includes a supply roller 101 that supplies a long sheet W before electrospinning, a heating device 117 that heats the long sheet W on which nanofibers are deposited, and a heating device. A take-up roller 102 that winds up the “long sheet W on which nanofibers are deposited” heated in 117. In addition, although the heating temperature of the heating apparatus 117 changes with kinds of the elongate sheet W and nanofiber, the elongate sheet W can be heated to the temperature of 50 to 300 degreeC, for example. Further, the “long sheet W on which nanofibers are deposited” in a heated state may be referred to as a nanofiber nonwoven fabric.

  Further, the conveying device 100 includes auxiliary rollers 103, 104, 105, and 106 provided between the supply roller 101 and the take-up roller 102, and the supply roller 101 side and the take-up roller 102 side from the electrospinning device 200, respectively. A first tension roller 107 and a second tension roller 108 for applying a predetermined tension to the long sheet W, and one end and the other end of the first tension roller 107, respectively. The first tension roller position adjusting mechanisms 109a and 109b for adjusting the position of the tension roller 107 and the one end and the other end of the second tension roller 108 are respectively provided to adjust the position of the second tension roller 108. Second tension roller position adjustment mechanism 11 for performing a, and a 110b.

  Further, the transport apparatus 100 outputs a take-up roller drive unit 111 that drives the take-up roller 102 and information for measuring the take-up amount of the take-up roller 102 (referred to as take-up amount measurement information). The “long sheet W on which nanofibers are deposited” that is provided between the quantity measurement information output device 112, the heating device 117, and the take-up roller 102 and heated by the heating device 117, that is, the nanofiber nonwoven fabric is provided on one surface. It has the support stand 113 supported from the side (lower surface side), and the cutting device 114 for cut | disconnecting the nanofiber nonwoven fabric which exists on the support stand 113 along the width direction of the said nanofiber nonwoven fabric.

  As the winding amount measurement information output device 112, for example, a laser distance sensor or the like can be used. When a laser distance sensor is used as the winding amount measurement information output device 112, the laser distance sensor measures the diameter of the nanofiber nonwoven fabric wound around the winding roller 102, and the measurement result is used as the winding amount measurement information. It is sent to the conveyance speed control unit 310 (see FIG. 5) of the apparatus 300. In addition, the cutting device 114 includes a pressing plate 115 that presses the nanofiber nonwoven fabric on the support base 113 and a cutter 116 that cuts the nanofiber nonwoven fabric in the width direction of the nanofiber nonwoven fabric when the nanofiber nonwoven fabric is cut. is doing.

The first tension roller position adjusting mechanisms 109a and 109b can adjust the vertical and horizontal positions of one end and the other end of the first tension roller 107 independently for each end. It has a mechanism to do.
The second tension roller position adjusting mechanisms 110a and 110b can independently adjust at least one position of one end and the other end of the second tension roller 108 in the vertical direction and the horizontal direction for each end. It has a mechanism to do.

  The first tension roller position adjusting mechanisms 109a and 109b operate the operation portions such as a handle provided at one end and the other end of the first tension roller 10 to thereby adjust each end of the first tension roller 107. Each end can be moved in at least one of the vertical direction and the horizontal direction independently for each end, thereby adjusting the inclination of the first tension roller 107 within a predetermined range. It is what. The first tension roller position adjusting mechanisms 109 a and 109 b can perform the same operation on the second tension roller 108.

  The first tension roller 107 and the second tension roller 108 are provided with the first tension roller position adjusting mechanisms 109a and 109b and the second tension roller position adjusting mechanisms 110a and 110b. The tension of the passing long sheet W can be set to an appropriate tension. Further, it is possible to correct the “deviation” in the width direction of the long sheet W with respect to the conveyance direction a, that is, the “deviation” when the long sheet W is displaced in the width direction (the direction along the y axis). As a result, the long sheet W can be conveyed in an optimum conveyance state for electrospinning.

  The conveyance speed control unit 310 controls the take-up roller driving unit 111 so that the conveyance speed of the long sheet W becomes a predetermined speed (a constant speed) based on the winding amount measurement information. In other words, the conveyance speed control unit 310 performs winding so that the conveyance speed of the long sheet W becomes a predetermined speed (constant speed) based on the winding amount measurement information sent from the winding amount measurement information output device 112. The take-up roller driving unit 111 is controlled.

As shown in FIGS. 1 and 2, the electrospinning apparatus 200 includes a conductive casing 210, an auxiliary belt device 220 that assists in transporting the long sheet W, and an insulating member 211 on the casing 210. A high-voltage (for example, 10 kV) between the collector 230 and the nozzle 240, the collector 230 attached via the nozzle 230, the nozzle block 250 having a plurality of nozzles 240 for discharging the polymer solution. ˜80 kV), and an electrospinning chamber 212 that defines a predetermined space covering the collector 230 and the nozzle block 250.
The electrospinning apparatus 200 includes a polymer solution supply apparatus 400 that supplies a polymer solution to the nozzle 240, although not shown in FIGS. 1 and 2 (see FIG. 3).

  The insulating member 211 is made of, for example, polyamide, polyacetal, polycarbonate, modified polyphenylene ether, polybutylene terephthalate, polyethylene terephthalate, amorphous polyarylate, polysulfone, polyether sulfone, polyphenylene sulfide, polyether ether ketone, polyimide, poly Ether imide, fluororesin, liquid crystal polymer, polobroylene, high density polyethylene or polyethylene can be preferably used.

As shown in FIGS. 1 and 2, the auxiliary belt device 220 includes an auxiliary belt 221 that rotates in synchronization with the conveyance speed of the long sheet W, a driving roller 222 that rotates the auxiliary belt 221, and a driving roller 222. And a driven roller 223 that rotates when the auxiliary belt 221 rotates.
In FIGS. 1 and 2, the left roller is the driving roller 222 and the right roller is the driven roller 223, but the opposite may be possible, and the rotation of the two rollers can be synchronized. Both may be drive rollers.

  The auxiliary belt 221 is made of an insulating and porous endless belt. The auxiliary belt 221 is preferably made of a polymer base material having a thickness of 0.7 mm to 10.0 mm. As the polymer, polymers such as polyethylene, polyacetylene, polyurethane, polypropylene, nylon and other polyamides, polyacetal, polycarbonate, modified polyphenylene ether, polybutylene terephthalate, polyethylene terephthalate, amorphous polyarylate, polysulfone, polyethersulfone, polyphenylenesulfone Preference is given to fido, polyetheretherketone, polyimide, polyetherimide, fluororesin, liquid crystal polymer and the like.

  The auxiliary belt device 220 is disposed so that the auxiliary belt 221 surrounds the collector 230. Then, the long sheet W is folded and conveyed on the driving roller 222 side while being in contact with the outer peripheral side of the auxiliary belt 221.

  Thus, by arranging the auxiliary belt 221 between the collector 230 and the long sheet W, the long sheet W is not attracted to the collector 230 to which the positive high voltage is applied. It will be transported smoothly. Further, since the auxiliary belt 221 is made of an insulating and porous endless belt, the electric field distribution formed between the collector 230 and the nozzle 240 is not greatly affected.

  The auxiliary belt 221 has a width wider than that of the collector 230. As a result, the auxiliary belt 221 reliably exists between the long sheet W and the collector 230, and the long sheet W is attracted to the collector 230, or smooth conveyance of the long sheet W is hindered. It is possible to reliably prevent this.

  As shown in FIG. 3, the nozzle block 250 has a plurality of (seven) tube bodies 271 to one end portions that are closed ends and the other end portions that are polymer solution supply ports. 277. As for the tubular bodies 271 to 277, individual tubular bodies are arranged along the width direction of the long sheet W. That is, each of the pipe bodies 271 to 277 is arranged along the y-y ′ direction in FIG. 3. In addition, each tubular body 271 to 277 is detachably attached to the nozzle block 250.

  A predetermined number of nozzles 240 are attached to these tubular bodies 271 to 277 at predetermined pitches along the longitudinal direction of the tubular body for each tubular body. The nozzle 240 and the pipe bodies 271 to 277 are made of a conductive member such as copper, stainless steel, or aluminum, and the nozzles 240 are electrically connected to the pipe bodies 271 to 277, for example. Is attached.

  As shown in FIG. 3, the polymer solution supply apparatus 400 includes two polymer solution tanks 411 and 412 (hereinafter referred to as “second”) that store a plurality of types of polymer solutions having different components (type A and type B). 1 polymer solution tank 411 and second polymer solution tank 412), and 7 polymer solutions for distributing the type A polymer solution and the type B polymer solution to the respective tubes 271 to 277 for each type of these polymer solutions. Distribution pipes 421 to 427. In addition, a polymer solution supply pump (see FIG. 5) that can supply the polymer solutions stored in the first polymer solution tank 411 and the second polymer solution tank 412 to each of the tubes 271 to 277 with a predetermined pressure applied. Not shown.) Is also provided.

  In the electrospinning apparatus 200 according to the embodiment, the first polymer solution tank 411 is a polymer solution tank that stores a type A polymer solution, and the second polymer solution tank 412 stores a type B polymer solution. The polymer solution tank Among the polymer solution distribution pipes 421 to 427, the polymer solution distribution pipes 421 to 424 are polymer solution distribution pipes for distributing the type A polymer solution, and the polymer solution distribution pipes 425 to 427 are the type B polymer solution. It is assumed that this is a polymer solution distribution pipe that distributes.

  The polymer solution distribution pipes 421 to 424 for circulating the type A polymer solution are connected to the respective polymer solution supply ports of the tubes 271, 273, 275, and 277 among the tubes 271 to 277, and the type B polymer The polymer solution distribution pipes 425 to 427 through which the solution is distributed are connected to the respective polymer solution supply ports of the pipe bodies 272, 274 and 276 among the pipe bodies 271 to 277.

The polymer solution distribution pipes 421 to 427 are provided with polymer solution supply amount control valves 431 to 437 for enabling control of the supply amount of the polymer solution. Note that “allowing control of the supply amount of the polymer solution” means that the opening amount of the polymer solution supply amount control valves 431 to 437 can be controlled from zero to the maximum. Thereby, the supply amount of the polymer solution can be arbitrarily controlled from zero to the maximum value.
In FIG. 3, the reference numerals indicating the nozzles 240 are given to only some of the nozzles for the sake of simplicity of the drawing.

  The nozzles 240 attached to the pipes 271 to 277 are attached to the pipes to which the same kind of polymer solution is assigned when the nozzle block 250 is viewed along the transport direction a. The rows in the conveyance direction by the nozzles are attached to the tubes so that they are arranged on a straight line having a predetermined angle with respect to the conveyance direction a on a plane parallel to the surface of the long sheet W.

  That is, in the electrospinning apparatus 200 according to the embodiment, as shown in FIG. 4, the conveying direction of the nozzle 240 attached to each tubular body 271, 273, 275, 277 to which the type A polymer solution is assigned. A row of a is attached to each of the tubes 271, 273, 275, 277 so that it is aligned with a straight line L 1 having a predetermined angle θ 1 with respect to the conveyance direction a on a plane parallel to the surface of the long sheet W. In addition, the row of the nozzles 240 attached to the pipes 272, 274, 276 to which the type B polymer solution is assigned is conveyed on a plane parallel to the surface of the long sheet W. The tubes 272, 274, and 276 are attached so as to be aligned with a straight line L2 having a predetermined angle θ2 with respect to the direction a.

  In FIG. 4, the nozzles 240 attached to the pipes 271, 273, 275, and 277 to which the type A polymer solution is assigned are indicated by white circles, and the type B polymer solution is assigned. The nozzle 240 attached to each tube 272, 274, 276 is shown as a gray circle.

  By attaching each nozzle 240 to each tube body 271 to 277 so that each nozzle 240 has such an arrangement, the longitudinal direction of the tube body to which the same kind of polymer solution is assigned (the width direction of the long sheet W) ) In the adjacent pipes are shifted from each other, so that the nanofiber made of the polymer solution of type A with respect to the long sheet W being conveyed along the conveyance direction a. And nanofibers made of the polymer solution of type B can be uniformly deposited.

  Further, as shown in FIG. 2, the nozzle block 250 is installed in the electrospinning chamber 212 of the electrospinning apparatus 200 so as to eject the polymer solution upward from the ejection port of each nozzle 240. Then, a predetermined polymer solution is discharged from the discharge port of each nozzle 240 while overflowing the polymer solution from the discharge port of each nozzle 240, and the long sheet W is electrospun to deposit nanofibers on the long sheet W.

  Therefore, the nozzle block 250 has a container shape capable of storing the overflowed polymer solution, and a polymer solution discharge port 253 (see FIG. 3) for discharging the polymer solution is provided on the bottom surface of the nozzle block 250. Is provided. A polymer solution discharge pipe 254 is connected to the polymer solution discharge port 253. In addition, if the polymer solution discharged | emitted from the polymer solution discharge port is collect | recovered for every kind of polymer solution, it is also possible to reuse each kind of polymer solution.

  Further, the nozzle block 250 is used in a state where the upper end opening surface is covered with a lid body 251 as shown in FIG. The lid body 251 is provided with nozzle through holes 252 corresponding to the nozzles 240 so that the nozzles 240 protrude upward.

  In addition, the nozzle block 250 can be reciprocated in the width direction of the long sheet W by a reciprocating drive unit 255 (see FIG. 5), and the collector 230 by an interval adjusting drive unit 256 (see FIG. 5). The interval between and can be adjusted. The reciprocating drive unit 255 and the interval adjustment drive unit 256 are controlled by the main controller 300. As the mechanism for reciprocating the nozzle block 250 in the width direction of the long sheet W and the mechanism for adjusting the distance from the collector 230, known mechanisms can be used. Illustrations and explanations of such structures are omitted.

  Incidentally, the power supply device 260 applies a predetermined voltage between the collector 230 and each nozzle 240. In order to apply a predetermined voltage between the collector 230 and each nozzle 240, the electric field according to the embodiment is provided. In the spinning device 200, one electrode (referred to as a positive electrode) of the power supply device 260 is connected to the collector 230, and the other electrode (referred to as a negative electrode) is connected to the tubular bodies 271 to 277 instead of the nozzle 240. I am doing so. The nozzle 240 side, that is, the tube bodies 271 to 277 side is set to the ground potential.

  If the nozzle block 250 is a conductive member and the nozzle block 250 and the pipe bodies 271 to 277 are electrically connected, the negative electrode of the power supply device 260 is the nozzle block 250. The negative electrode of the power supply device 260 may be connected to the housing 210 as long as the nozzle block 250 and the housing 210 are electrically connected. . In any case, the nozzle 240 side, that is, the tube bodies 271 to 277 side, the nozzle block 250 side, or the housing 210 side is set to the ground potential.

In this way, by setting the nozzle 240 side, that is, the pipe bodies 271 to 277 side, the nozzle block 250 side or the casing 210 side to the ground potential, the nozzle 240, the pipe bodies 271 to 277, the nozzle block 250 and the casing 210 are set. In addition, all of the polymer solution before being discharged from the nozzle 240 and the polymer solution supply device 400 are at the ground potential.
As a result, the safety of the operator who operates the electrospinning apparatus 200 and the nanofiber manufacturing apparatus 1 can be ensured, and the polymer solution supply apparatus 400 does not need to have a high withstand voltage specification.

  The electrospinning apparatus 200 configured as described above is preferably installed in a room adjusted to an atmosphere having a temperature of 20 ° C. to 40 ° C. and a humidity of 20% to 60%.

  The main control device 300 has a function of controlling the electrospinning device 200 and the transport device 100. Specifically, as shown in FIG. 5, the reciprocating motion control unit 310 that controls the transporting speed based on the winding amount measurement signal and the reciprocating motion driving unit 255 that reciprocates the nozzle block 250. The movement control unit 320 and the interval adjustment control unit 330 that controls the interval adjustment driving unit 256 for adjusting the interval between the nozzle blocks 250 are provided.

  In addition to these controls, the main control device 300 has a function of controlling the power supply device 260 and the auxiliary belt device 220 in the electrospinning device 200, and controls the heating device 117 in the transport device 100. It has a function. In the case of considering the nanofiber manufacturing apparatus 1 as a whole, it also has a function of controlling a VOC processing apparatus (not shown), an inert gas control apparatus (not shown), and the like.

Further, if a drive unit such as a motor is provided in the first tension roller position adjusting mechanisms 109a and 109b, the second tension roller position adjusting mechanisms 110a and 110b, the cutting device 114, etc., the first tension roller 107 and the second tension roller 108 are provided. It is also possible to perform the position control and the cutting control of the cutting device 114 by the main control device 300. When the cutting control of the cutting device 114 is performed, when the winding amount of the nanofiber nonwoven fabric reaches a predetermined amount, the electrospinning operation by the electrospinning device 200 is stopped and the nanofiber nonwoven fabric is wound by the winding roller 102. A signal for operating the holding plate 115 and the cutter 116 is output in a state where the conveying operation of the long sheet W such as taking is stopped. When the nanofiber nonwoven fabric is cut by the cutter 116, the nanofiber nonwoven fabric is cut by the cutter 116 in a state where the nanofiber nonwoven fabric is pressed by the pressing plate 115.

2. Nanofiber manufacturing method using the nanofiber manufacturing apparatus according to the embodiment will be described below a method of producing a nanofiber nonwoven fabric using a nanofiber manufacturing apparatus 1 according to the embodiment configured as described above.

  First, the long sheet W is set on the conveying apparatus 100, and then the long sheet W is wound by the winding roller 102 while being fed from the supply roller, thereby being conveyed at a predetermined conveying speed. Then, in the electrospinning apparatus 200, the nanofibers are sequentially deposited by discharging the polymer solution onto the long sheet W from the nozzles 240 attached to the tube bodies 271 to 277.

  Before starting such an operation, the interval between the collector 230 and the nozzle block 250 can be adjusted to an optimal interval by the interval adjustment driving unit 256. The distance between the collector 230 and the nozzle block 250 can be determined in consideration of the spinning conditions of the electrospinning apparatus 200, the type of polymer solution, the average diameter of the nanofibers, the thickness of the nanofiber nonwoven fabric to be manufactured, and the like. As a result, electrospinning can be performed in a state where the distance between the nozzle block 250 and the collector 230 is optimally set.

  By the way, in the nanofiber manufacturing apparatus 1 according to the embodiment, the first polymer solution tank 411 stores the type A polymer solution, and the second polymer solution tank 412 stores the type B polymer solution. Has been. Then, the type A polymer solution is supplied to the pipe bodies 271, 273, 275, 277 through the polymer solution distribution pipes 421 to 424, and the type B polymer solution is supplied through the polymer solution distribution pipes 425 to 427. Are supplied to the tubes 272, 274, 276.

  For this reason, the type A polymer solution and the type B polymer solution are alternately discharged from the nozzles 240 of the tubes 271 to 277 to the long sheet W being conveyed in the conveyance direction a. Is done. As a result, nanofibers in a state in which the type A polymer solution and the type B polymer solution are mixed can be deposited on the long sheet W.

  Further, when performing the operation of sequentially depositing nanofibers on the long sheet W, the polymer solution is applied to the long sheet W while the nozzle block 250 is reciprocated in the width direction of the long sheet W by the reciprocating motion driving unit 255. The operation of discharging is performed. Note that the reciprocating motion cycle of the reciprocating motion driving unit 255 is set based on the arrangement pitch of the nozzles 240 and the conveying speed of the long sheet W. That is, with respect to the long sheet W that is being conveyed in the conveyance direction a, the reciprocating motion cycle is set so that the discharge position of each nozzle 240 does not overlap with the discharge positions of other nozzles as much as possible. Thereby, the amount of polymer fibers deposited on the long sheet W can be made uniform.

  Thus, after depositing polymer fibers on the long sheet W, the nanofiber nonwoven fabric can be produced by heating the “long sheet W on which nanofibers are deposited” with the heating device 117. In the nanofiber manufacturing apparatus 1 according to the embodiment, as described above, nanofibers in a state where different types of polymer solutions are mixed can be deposited on the long sheet W and heated. The nanofiber non-woven fabric produced by doing so becomes a nanofiber non-woven fabric having a quality different from that of the nanofiber non-woven fabric produced by one kind of polymer solution, and can be used for a wider range of applications.

  The nanofiber nonwoven fabric produced in this way is wound up by a winding roller 102. At this time, the winding amount measurement information output device 112 measures the winding amount of the nanofiber nonwoven fabric wound around the winding roller 102, and uses the measurement result as the winding amount measurement information as the conveyance speed of the main controller 300. Output to the control unit 310. The conveyance speed control unit 310 controls the winding roller driving unit 111 so that the conveyance speed of the long sheet W becomes a constant speed based on the winding amount measurement information.

  In addition, when the winding amount reaches a predetermined amount, the nanofiber nonwoven fabric can be cut by the cutting device 114. When the nanofiber nonwoven fabric is cut by the cutting device 114, the nanofiber nonwoven fabric is pressed by the pressing plate 115 and is cut by the cutter 116. When the nanofiber nonwoven fabric is cut, the electrospinning operation by the electrospinning apparatus 200 is stopped and the conveyance operation of the long sheet W such as winding of the nanofiber nonwoven fabric by the winding roller 102 is stopped.

  As a result, a predetermined amount of the nanofiber nonwoven fabric is wound on the winding roller 102. Then, the winding roller 102 on which the nanofiber nonwoven fabric is not wound is set, the tip of the subsequent nanofiber nonwoven fabric is wound around the winding roller 102, and the nanofiber nonwoven fabric that is sequentially manufactured is wound. go. By sequentially performing such operations, nanofiber nonwoven fabrics wound by a predetermined winding amount can be manufactured one after another.

  Note that the cutting operation by the cutting device 114 can be automatically performed by the main control device 300. That is, in the main control device 300, when the amount of the nanofiber nonwoven fabric taken up reaches a predetermined amount, the electrospinning operation by the electrospinning device 200 is stopped and the nanofiber nonwoven fabric is taken up by the take-up roller 102. A signal for operating the presser plate 115 and the cutter 116 is output in a state where the transporting operation is stopped. When the nanofiber nonwoven fabric is cut by the cutter 116, the nanofiber nonwoven fabric is cut by the cutter 116 in a state where the nanofiber nonwoven fabric is pressed by the pressing plate 115. Thereby, cutting operation can be performed automatically.

  Further, when it is necessary to adjust the tension of the long sheet W or the position in the width direction of the long sheet W during the production of the nanofiber nonwoven fabric, the first tension roller position adjusting mechanism By appropriately adjusting the 109a, 109b and the second tension roller position adjusting mechanisms 110a, 110b, the long sheet W can be set to the optimum tension, and the position of the long sheet W in the width direction is set to the optimum position. be able to.

  Here, the spinning conditions in the nanofiber manufacturing method according to the embodiment are exemplarily shown. As the long sheet W, nonwoven fabrics, woven fabrics, knitted fabrics and the like made of various materials can be used. The long sheet W may have a thickness of, for example, 5 μm to 500 μm.

  Examples of the polymer used as a raw material for the nanofiber include polylactic acid (PLA), polypropylene (PP), polyvinyl acetate (PVAc), polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polyethylene naphthalate (PEN), Polyamide (PA), polyurethane (PU), polyvinyl alcohol (PVA), polyacrylonitrile (PAN), polyetherimide (PEI), polycaprolactone (PCL), polylactic glycolic acid (PLGA), polyvinylidene fluoride (PVDF), Silk, cellulose, chitosan and the like can be used.

  Examples of the solvent used for the polymer solution include dichloromethane, dimethylformamide, dimethyl sulfoxide, methyl ethyl ketone, chloroform, acetone, water, formic acid, acetic acid, cyclohexane, THF, decahydronaphthalene (Decalin), dimethylformamide (DMAc), and the like. Can do. A plurality of types of solvents may be mixed and used. The polymer solution may contain an additive such as a conductivity improver.

Moreover, the conveyance speed of the long sheet W can be set to 5 mm / min-10 m / min, for example. The voltage applied to the nozzle, collector 230 and nozzle block 250 can be set to 10 kV to 80 kV.
Moreover, the temperature of the electrospinning chamber 212 in the electrospinning apparatus 200 can be set to a temperature of 20 ° C. to 40 ° C., for example. The humidity of the electrospinning chamber 212 can be set to 20% to 60%, for example.

  By the way, when the electrospinning is performed, the polymer solution overflowed from the nozzle 240 is discharged from the polymer solution discharge port 253 through the polymer solution discharge pipe 254, and the discharged polymer solution is recovered to form nanofibers. When it is reused as a raw material, it can be reused by providing a polymer solution recovery device (not shown).

  In this case, it is preferable to collect the type A polymer solution and the type B polymer solution separately. The recovered type A polymer solution is transferred to the type A regeneration tank in the polymer solution recovery device, and the recovered type B polymer solution is transferred to the type B regeneration tank in the polymer solution recovery device. Thereafter, the composition of each of the collected polymer solutions of type A and type B is measured, and a solvent and other necessary components are added to the polymer solutions of type A and type B according to the measurement results. .

  By performing such a treatment, the recovered type A and type B polymer solutions are converted into the original type A and type B polymer solutions, that is, the type A polymer solution stored in the first polymer solution tank 411 and It is possible to regenerate the polymer solution having the same or very close composition as that of the type B polymer solution stored in the second polymer solution tank 412.

  In order to realize this, the nozzle block 250 divides the inside corresponding to each of the tubes 271 to 277 to form a polymer solution recovery chamber corresponding to each of the tubes 271 to 277, and each tube 271 to A polymer solution outlet 253 is provided in each polymer solution recovery chamber corresponding to H.277. A polymer solution discharge pipe 254 is connected to each of these polymer solution discharge ports, and the types A and B of polymer solutions discharged through the respective polymer solution discharge pipes are respectively corresponding types of regeneration tanks. To supply. By setting it as such a structure, the polymer solution which overflowed can be collect | recovered for every kind, and can be made reproducible for every kind.

3. Effects of the electrospinning apparatus and nanofiber manufacturing apparatus according to the embodiment According to the electrospinning apparatus 200 according to the embodiment, each nozzle 240 is not directly attached to the nozzle block 250, but a predetermined number of each. It is attached to the pipe bodies 271 to 277. For this reason, when the nozzle 240 is repaired or replaced, only the tube to be repaired or replaced may be removed from the nozzle block 250. As a result, the nozzle can be repaired or replaced on a tube-by-tube basis, so that maintenance is facilitated. Further, for example, the supply amount of the polymer solution is controlled for each tubular body arranged in the width direction of the long sheet W, or different types of polymer solutions are supplied to the respective tubular bodies 271 to 277. Can do.

  When the supply amount of the polymer solution is controlled for each of the bodies 271 to 277, it can be easily performed by the polymer solution supply amount control valves 431 to 437 provided corresponding to the pipe bodies 271 to 277, respectively. If necessary, it is possible not to supply the polymer solution to a specific tube.

Further, as described in the above embodiment, the type A polymer solution is supplied to the pipes 271, 273, 275, and 277, and the type B polymer solution is supplied to the pipes 272, 274, and 276. In addition, different types of polymer solutions can be supplied for each tube. Thereby, the nanofiber nonwoven fabric manufactured by heating the composite nanofiber of the state with which the polymer solution of the kind A and the polymer solution of the kind B were mixed can be deposited on the long sheet W. The nanofiber nonwoven fabric having a quality different from that of the nanofiber nonwoven fabric produced by one kind of polymer solution can be used for a wider range of applications.
Thus, according to the electrospinning apparatus 200 according to the embodiment, various ways of supplying the polymer solution can be set.

  In addition, since a predetermined number of nozzles 240 are attached to each of the pipe bodies 271 to 277, when the nozzle 240 is repaired or replaced, only the pipe body to be repaired or replaced is replaced with the nozzle block 250. Since the nozzle can be repaired or replaced in units of tubes, an effect of facilitating maintenance can be obtained.

  Further, as shown in FIG. 4, the nozzles 240 attached to the pipes 271 to 277 are arranged on the straight lines L1 and L2 having inclinations of predetermined angles θ1 and θ with respect to the transport direction a. To 277. For this reason, since the nozzle 240 becomes a position shifted from each other in the longitudinal direction of each of the tubular bodies 271 to 277, the polymer solution can be discharged evenly on the long sheet W, and has a uniform thickness. Nanofibers can be produced.

  In addition, according to the electrospinning apparatus 200 according to the embodiment, the nozzle 240 side, that is, the tube bodies 271 to 277 side, the nozzle block 250 side, or the housing 210 side is set to the ground potential. As a result, all of the polymer solution before being discharged from each nozzle 240 and the polymer solution supply device 400 are at ground potential. For this reason, it is possible to ensure the safety of the operator who operates the electrospinning apparatus 200 and the nanofiber manufacturing apparatus 1, and it is not necessary to make each of these components have a high withstand voltage specification.

  Further, according to the electrospinning apparatus 200 according to the embodiment, since the nozzle block 250 can be reciprocated at a predetermined cycle along the width direction of the long sheet W, the amount of nanofibers deposited on the long sheet W can be reduced. It becomes possible to make uniform. In addition, since the distance between the nozzle block 250 and the collector 230 can be adjusted, it is possible to perform electrospinning under optimum conditions.

  Further, according to the nanofiber manufacturing apparatus 1 according to the embodiment, the positions of the end portions of the first tension roller 107 and the second tension roller 108 can be adjusted, and thus the first tension roller 107 and the second tension roller 108 are adjusted. As a matter of course, it is possible to set the tension of the long sheet W to the appropriate tension, and it is possible to easily correct the “displacement” in the width direction of the long sheet W with respect to the conveying direction a. The long sheet W can always be conveyed in an appropriate state. Thereby, a high-quality nanofiber nonwoven fabric having a uniform thickness can be produced.

  Moreover, according to the nanofiber manufacturing apparatus 1 which concerns on embodiment, the winding amount of the nanofiber nonwoven fabric wound by the winding roller 102 is measured, and a conveyance speed is controlled based on the measured winding amount. As a result, the conveyance speed of the long sheet W passing through the electrospinning apparatus 200 can be maintained at a constant speed, thereby producing a high-quality nanofiber nonwoven fabric having a uniform thickness. it can.

  Moreover, according to the nanofiber manufacturing apparatus 1 according to the embodiment, since the cutting device 114 is provided between the heating device 117 and the winding roller 102, a predetermined amount of nanofiber nonwoven fabric is wound on the winding roller. Once done, the nanofiber nonwoven can be cut. In this case, a winding roller on which the nanofiber nonwoven fabric is not wound is attached, and the tip of the subsequent nanofiber nonwoven fabric is connected to the winding roller. By repeating such an operation, the nanofiber nonwoven fabric that has been wound up by a predetermined amount can be easily taken out.

4). Modified Example of Polymer Solution Supply Device 400 FIG. 6 is a view for explaining a first modified example of the polymer solution supply device 400. 6A shows a case where the pipe bodies 271 to 277 are divided into two groups, and FIG. 6B shows a case where the pipe bodies 271 to 277 are divided into three groups.

  FIG. 7 is a view for explaining a second modification of the polymer solution supply apparatus 400. FIG. 8 is a view for explaining a third modification of the polymer solution supply apparatus 400.

  6 to 8, the polymer solution supply device 400 and the pipe bodies 271 to 277 are schematically shown in a simplified manner. Moreover, illustration of each nozzle 240 attached to each tube body 271 to 277 is omitted.

[First Modification]
As shown in FIG. 6A, the first modified example of the polymer solution supply apparatus 400 divides the tubes 271 to 277 into a group of a predetermined number of tubes arranged in the transport direction a. In this configuration, different types of polymer solutions are supplied for each group. In the example shown to Fig.6 (a), the pipe bodies 271-274 of the pipe bodies 271-277 are set as the 1st group G1, and the pipe bodies 275-277 of the pipe bodies 271-277 are set as the 2nd group G2. The type A polymer solution is supplied to the tubes 271 to 274 of the first group G1, and the type B polymer solution is supplied to the tubes 275 to 277 of the second group G2.

  Note that the number of groups and the number of tubes in each group are arbitrary. For example, if the number of tubes is 7 (tubes 271 to 277) as in the embodiment, as shown in FIG. 6B, the whole is divided into three groups G1, G2, and G3. The first group G1 has two (tubes 271 and 272), the second group G2 has three (tubes 273 to 275), the third group G3 has two (tubes 276 and 277), One group of pipes 271 and 272 are supplied with a type A polymer solution, and a second group of pipes 273 to 275 are supplied with a type B polymer solution, and a third group of pipes 276 and 277 are supplied. It is also possible to supply a type A polymer solution.

  If a polymer solution of type C different from types A and B can also be used, it is possible to supply the polymer solution of type C to the third group of tubes 276 and 277.

  According to the first modification, the nanofiber nonwoven fabric produced according to FIG. 6A has a nanofiber made of a polymer solution of type A deposited on the surface of the long sheet W, and a polymer solution of type B thereon. The nanofiber nonwoven fabric produced according to FIG. 6 (b) was obtained by using the type C polymer solution in addition to the type A and type B polymer solutions as the polymer solution. Then, nanofibers made of a type A polymer solution are deposited on the surface of the long sheet W, nanofibers made of a type B polymer solution are deposited thereon, and further, a type C polymer solution is made thereon. Nanofibers are deposited.

[Second Modification]
As shown in FIG. 7, the second modification of the polymer solution supply apparatus 400 is a polymer solution distribution pipe 421 to distribute a type A polymer solution connected to each polymer solution supply port of each tube 271 to 277. The polymer solution distribution pipes 421 to 424 that distribute the polymer solution 424 and the type B polymer are respectively provided as a single polymer solution distribution pipe 420A and 420B, and the polymer solution distribution pipe 420A is connected to the first polymer solution tank 411. The polymer solution distribution pipe 420B is configured to be connected to the second polymer solution tank 412.

  When the polymer solution supply device 400 is configured as shown in FIG. 7, the polymer solution supply amount control valves 431 to 437 (not shown in FIG. 7) correspond to the pipes 271 to 277 as in FIG. As a matter of course, the polymer solution distribution pipes 421 to 427 may be provided. However, when the supply amount can be controlled collectively for each type of polymer solution, as shown in FIG. Further, the polymer solution distribution pipe 420A is provided with a polymer solution supply amount control valve 430A for controlling the supply amount of the type A polymer solution, and the polymer solution distribution pipe 420B is supplied with the supply amount of the type B polymer solution. It is also possible to provide a polymer solution supply amount control valve 430B for controlling. By setting it as such a structure, supply_amount | feed_rate can be collectively controlled for every kind of polymer solution.

  Of course, the configuration of the polymer solution distribution pipe as shown in the second modification can also be applied to the polymer solution supply apparatus 400 shown in the first modification shown in FIG.

[Third Modification]
As shown in FIG. 8, the third modification of the polymer solution supply apparatus 400 is configured to partition a single tank (referred to as a polymer solution tank 413) and provide a plurality of polymer solution storage chambers. Is. That is, in the nanofiber manufacturing apparatus 1 according to the above embodiment, since there are two types of polymer solutions (a type A polymer solution and a type B polymer solution), two polymers are contained in the polymer solution tank 413. Solution storage chambers 413A and 413B (hereinafter referred to as first polymer solution storage chamber 413A and second polymer solution storage chamber 413B) are provided. The first polymer solution storage chamber 413A is a polymer solution storage chamber that stores a type A polymer solution, and the second polymer solution storage chamber 413B is a polymer solution storage chamber that stores a type B polymer solution. To do.

  The manner of piping of the polymer solution circulation pipes 421 to 427 from the first polymer solution storage chamber 413A and the second polymer solution storage chamber 413B to the pipe bodies 271 to 277 is the same as described in the above embodiment (see FIG. 3). ), The type A polymer solution and the type B polymer solution may be alternately supplied to each of the pipe bodies 271 to 277, or the first modification (see FIG. 6) or the second modification ( It may be a supply method as shown in FIG.

  Although the present invention has been described based on the above embodiment, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the present invention. Variations as shown in FIG.

  (1) In the above embodiment, the case where there are two types of polymer solutions (a polymer solution of type A and a polymer solution of type B) has been described. However, the types of polymer solutions are not limited to two, and 3 There may be more than one type.

  (2) In the above embodiment, the number of the tubular bodies is seven (tubular bodies 271 to 277), but is not limited to seven. Moreover, the number of nozzles attached to each tube does not necessarily need to be the same in each tube.

  (3) In the above embodiment, the tubes 271 to 277 do not necessarily have to be arranged so as to be orthogonal to the transport direction a on a plane parallel to the long sheet W, but to the transport direction a. You may make it arrange | position in the state which has some inclination.

  (4) In the above embodiment, the case where there is one electrospinning apparatus 200 has been described as an example, but the present invention is not limited to this. For example, two or more electrospinning apparatuses may be provided.

  (5) In the above embodiment, the nanofiber production apparatus of the present invention has been described using the electrospinning apparatus 200 having the nozzle block 250 with the nozzle 240 facing upward, but the present invention is limited to this. is not. For example, the present invention can be applied to a nanofiber manufacturing apparatus including an electrospinning apparatus having a nozzle block with a nozzle facing downward or an electrospinning apparatus having a nozzle block with a nozzle facing sideways.

  (6) In the above-described embodiment, the case where the positive electrode of the power supply device 260 is connected to the collector 230 and the negative electrode of the power supply device 260 is connected to the tubular bodies 271 to 277 has been described as an example. Is not to be done. For example, the negative electrode of the power supply device 260 may be connected to the collector 230, and the positive electrode of the power supply device 260 may be connected to the tubular bodies 271 to 277.

  (7) In the above embodiment, the coping method at the time of occurrence of abnormality during electrospinning was not mentioned, but the electrospinning apparatus 200 was operated continuously for a long time. When an abnormality occurs in 200, it is possible to provide a function that can immediately detect the abnormality.

  For example, the power supply device 260 has a function of measuring a current amount and transmitting the measurement value to the main control device 300, and the main control device 300 has an abnormal value of the current amount of the power supply device 260. It is also possible to have a function of controlling the power supply device 260.

  Thereby, when electrospinning is performed in a state where a predetermined voltage is applied between the collector 230 and the tubular bodies 271 to 277, it is confirmed that a current exceeding the upper limit is supplied from the power supply device 260 to the electrospinning device 200. When detected, main controller 300 can control power supply device 260 to stop the supply of current. Conversely, when it is detected that a current below the lower limit is supplied to the electrospinning apparatus 200 from the power supply apparatus 260, the main control apparatus 300 causes the power supply apparatus 260 to output a warning signal indicating an abnormality. It is also possible to control.

  When the main control device 300 controls the power supply device 260 to stop the current supply, the main control device 300 supplies the inert gas to the electrospinning device with respect to the inert gas supply device (not shown). A signal to be supplied to the 200 electrospinning chambers 212 may be transmitted. Thereby, accidents such as fire can be prevented in advance, and it becomes possible to realize a nanofiber manufacturing apparatus with higher safety.

  (8) In the above embodiment, the shape of the nozzle 240 is not mentioned, but for example, the nozzle tip is cut along a plane that obliquely intersects the central axis of the nozzle 240. It is also possible to use a nozzle. By making the nozzle tip portion in such a shape, the polymer solution overflowing from the nozzle tip portion flows down quickly without staying at the nozzle tip portion. For this reason, the amount of the solvent volatilized from the polymer solution in the process of electrospinning can be extremely reduced, and the amount of polymer solidified product generated in the vicinity of the discharge port of the nozzle 240 can be extremely reduced.

  (9) In the above embodiment, the conveyance speed of the long sheet W is set to a constant speed by controlling the conveyance speed by the amount of the nanofiber nonwoven fabric wound around the winding roller 102. In addition to controlling the conveyance speed by the amount of winding, for example, measuring the air permeability of the deposited nanofiber or the thickness of the deposited nanofiber, and appropriately controlling the conveyance speed based on the measurement result You can also. In this case, the conveyance speed is controlled so that the permeability of the deposited nanofibers or the thickness of the deposited nanofibers is as close as possible to a predetermined value. Thereby, it becomes possible to produce the nanofiber nonwoven fabric which has uniform air permeability or thickness.

  In addition, the air permeability of the nanofiber in this case refers to the air permeability when the air permeability is measured in a state where the nanofiber layer deposited on the long sheet W and the long sheet W are laminated. . The thickness of the nanofiber refers to the thickness when the thickness is measured in a state where the nanofiber layer deposited on the long sheet W and the long sheet W are laminated.

  (10) In the above embodiment, the case where one nozzle block is disposed in one electrospinning apparatus 200 is exemplified, but the present invention is not limited to this. For example, one electrospinning apparatus 200 may have two or more nozzle blocks. In this case, as described in the above-described embodiment, a predetermined number of tube bodies to which a predetermined number of nozzles are attached are arranged in each nozzle block. It is also possible to adjust the distance between the nozzle block and the reciprocating motion and the collector 230.

  When reciprocating for each nozzle block, each nozzle block can be reciprocated with the same period, or each nozzle block can be reciprocated with a different period. Moreover, when adjusting the space | interval between the collector 230 for every nozzle block, each nozzle block can also be made into the same space | interval, and it can also set to a space | interval different for every nozzle block.

  (11) The configuration of the polymer solution supply apparatus 400 is as shown in the above embodiment (see FIG. 3), as shown in the first modification (see FIG. 6), and as shown in the second modification. The present invention is not limited to such a configuration (see FIG. 7), and various modifications can be made.

  (12) In the above embodiment, the case where the heating device 117 is provided in the transport device 100 is illustrated, but depending on the type of nanofiber to be manufactured, the model of the nanofiber manufacturing device, etc., it is necessary to provide the heating device. There may be no.

  DESCRIPTION OF SYMBOLS 1 ... Nano fiber manufacturing apparatus, 100 ... Conveyance apparatus, 101 ... Supply roller, 102 ... Winding roller, 103, 104, 105, 106 ... Auxiliary roller, 107 ... 1st Tension roller, 108 ... second tension roller, 109a, 109b ... first tension roller position adjustment mechanism, 110a, 110b ... second tension roller position adjustment mechanism, 111 ... take-up roller drive unit, DESCRIPTION OF SYMBOLS 112 ... Winding amount measurement information output device (laser distance sensor), 113 ... Support stand, 114 ... Cutting device, 115 ... Holding plate, 116 ... Cutter, 117 ... Heating device , 200 ... electrospinning device, 210 ... housing, 211 ... insulating member, 212 ... electrospinning chamber, 220 ... auxiliary belt device 221 ... auxiliary belt, 230 ... collector, 240 ... nozzle, 250 ... nozzle block, 255 ... reciprocating motion drive unit, 256 ... interval adjustment drive unit, 260 ... power supply device, 271- 277 ... Tube, 300 ... Main controller, 310 ... Conveying speed controller, 400 ... Polymer solution supply device, 410 ... Polymer solution tank, 411 ... First polymer solution tank 412 ... 2nd polymer solution tank, 413A ... 1st polymer solution storage chamber, 413B ... 2nd polymer solution storage chamber, 421-427 ... polymer solution distribution pipe, 431-437 ... Polymer solution supply amount control valve, a ... conveying direction, W ... long sheet

Claims (15)

A collector, a nozzle block provided two-dimensionally with a plurality of nozzles for discharging a polymer solution provided at a position facing the collector, a polymer solution supply device for supplying the polymer solution to the nozzle, and the collector And a power supply device that applies a high voltage between the nozzle and the nanofibers by discharging the polymer solution onto a long sheet that is transported between the collector and the nozzle in a predetermined transport direction. An electrospinning device for deposition,
The polymer solution supply device includes:
A polymer solution tank storing a plurality of types of polymer solutions having different components, and a plurality of polymer solution distribution pipes for distributing the plurality of types of polymer solutions for each type of polymer solution,
The nozzle block is
A tube body, which is disposed along the width direction of the long sheet and has one end portion as a closed end and the other end portion as a polymer solution supply port, is arranged along the conveying direction of the long sheet. And a plurality of the nozzles are attached to each of the plurality of tube bodies along the longitudinal direction of each of the tube bodies, and the polymer solution supply of each of the tube bodies The mouth is connected to a polymer solution distribution pipe for distributing the type of polymer solution allocated to the tube so that the type of polymer solution allocated to the tube is supplied. Electrospinning device. The electrospinning apparatus according to claim 1,
Each of the tubular bodies is detachably attached to the nozzle block. In the electrospinning apparatus according to claim 1 or 2,
The polymer solution distribution pipe is provided with a polymer solution supply amount control valve for controlling the supply amount of the polymer solution for each tube, corresponding to each tube. Spinning device. In the electrospinning apparatus according to any one of claims 1 to 3,
The electrospinning apparatus according to claim 1, wherein the polymer solution distribution pipe is provided with a polymer solution supply amount control valve capable of collectively controlling a supply amount of the polymer solution for each type of the polymer solution. In the electrospinning apparatus according to any one of claims 1 to 4,
The electrospinning apparatus, wherein the polymer solution tank is individually provided for each type of the polymer solution. In the electrospinning apparatus according to any one of claims 1 to 4,
The electrospinning apparatus is characterized in that the polymer solution tank is internally divided so as to form a plurality of polymer solution storage chambers capable of storing the plurality of types of polymer solutions for each type of the polymer solution. . In the electrospinning apparatus according to any one of claims 1 to 6,
The nozzles attached to the pipes are arranged in the direction of conveyance by the nozzles attached to the pipes to which the same type of polymer solution is assigned when the nozzle block is viewed along the conveyance direction. An electrospinning apparatus, wherein the rows are attached to the tubes so that the rows are arranged on a straight line having a predetermined angle with respect to the conveying direction on a plane parallel to the surface of the long sheet. . In the electrospinning apparatus according to any one of claims 1 to 7,
Each nozzle and each tube is made of a conductive member, and one of the positive electrode and the negative electrode of the power supply device is connected to the collector, and the other of the positive electrode and the negative electrode of the power supply device The electrode is connected to each tube body, and the side of each tube body is at a ground potential. In the electrospinning apparatus according to any one of claims 1 to 8,
The electrospinning apparatus according to claim 1, further comprising a reciprocating drive unit configured to reciprocate the nozzle block in a predetermined cycle along the width direction of the long sheet. In the electrospinning apparatus according to any one of claims 1 to 9,
An electrospinning apparatus, further comprising an interval adjustment driving unit that drives the nozzle block so as to adjust an interval between the nozzle block and the collector. A nanofiber manufacturing apparatus comprising: a conveying device that conveys a long sheet in a predetermined conveying direction; and an electrospinning device that electrospins a long sheet that is conveyed in the predetermined conveying direction,
The said electrospinning apparatus is an electrospinning apparatus in any one of Claims 1-10, The nanofiber manufacturing apparatus characterized by the above-mentioned. In the nanofiber manufacturing apparatus according to claim 11,
The transfer device
A supply roller for supplying the long sheet;
A take-up roller for winding the long sheet on which nanofibers are deposited by the electrospinning apparatus while transporting the long sheet at a predetermined transport speed;
A take-up roller drive unit for driving the take-up roller;
A first tension roller and a second tension roller which are provided on the supply roller side and the take-up roller side from the electrospinning device, respectively, and for applying a predetermined tension to the long sheet;
The nanofiber manufacturing apparatus characterized by having. In the nanofiber manufacturing apparatus according to claim 12,
The first tension roller is a first tension roller capable of independently adjusting at least one position in the vertical direction and the horizontal direction of one end and the other end of the first tension roller for each end. A position adjustment mechanism,
The second tension roller is a second tension roller capable of independently adjusting at least one of the vertical and horizontal positions of one end and the other end of the second tension roller for each end. A nanofiber manufacturing apparatus having a position adjusting mechanism. In the nanofiber manufacturing apparatus according to claim 12 or 13,
The transfer device
A winding amount measurement information output device that outputs winding amount measurement information indicating the winding amount of the long sheet on which the nanofibers are deposited in the winding roller;
A conveyance speed control device for controlling the winding roller drive unit based on the winding amount measurement information output from the winding amount measurement information output device;
An apparatus for producing nanofibers, further comprising: In the nanofiber manufacturing apparatus according to any one of claims 12 to 14,
The transfer device
A cutting device provided at a predetermined position between the electrospinning device and the take-up roller for cutting the long sheet on which the nanofibers are deposited along the width direction of the long sheet; A feature of nanofiber production equipment.

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