This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2018-081332, filed on Apr. 20, 2018, the entire contents of which are incorporated herein by reference.
Embodiments described herein generally relate to an electrospinning head, and an electrospinning apparatus using an electrospinning head.
Conventionally, an electrospinning apparatus which forms a fiber film on a base material using an electrospinning method is known. The conventional apparatus discharges a raw material liquid (fiber) toward the base material from an electrospinning head (hereinafter, simply called a head), while conveying the base material.
The above-described apparatus, in order to control spread of the fiber which has been discharged from the head and is flying, in the width direction of the base material, has control units which are arranged at the both ends of the head and extend in the base material direction from the head.
Further, the conventional apparatus, in order to induce the fiber the spread of which has been controlled by the control units onto the base material, has induction units which are respectively provided between the control units and the base material.
According to one embodiment, an electrospinning head has a nozzle unit and a control body. The nozzle unit is arranged opposite to a base material, is applied with a voltage, and thereby is capable of discharging a raw material liquid of fiber. The control body is arranged in the vicinity of the nozzle unit so as to extend to an outside of a spinning space between the base material and the nozzle unit. Further, the control body is applied with a voltage of the same polarity as the voltage to be applied to the nozzle unit, and thereby is capable of making an electric field to be generated at the periphery of the nozzle unit.
Hereinafter, embodiments will be described, with reference to the drawings. In addition, X, Y, Z directions in the respective drawings are common directions throughout the whole drawings, and are directions orthogonal to each other. In addition, the X direction is a direction in which a nozzle 311a extends toward a base material 40, and an X1 direction is a conveying direction of the base material 40 in a horizontal conveying path. In addition, the Y direction is a direction orthogonal to a width direction of the base material 40, and is a conveying direction of the base material 40 in a vertical conveying path 64. In addition, the Z direction is the width direction of the base material 40, and is a direction in which nozzles 311a of nozzle units 311 included in a head 31 are arranged.
To begin with, the whole of the embodiment will be schematically described.
The apparatus 10 is an example of an apparatus to form a fiber film on the base material 40 by a well-known electrospinning method. The apparatus 10 has the conveying path 64 (hereinafter, called the vertical conveying path 64) to convey the base material 40 in the Y direction. The head 31 discharges a raw material liquid (fiber) toward the base material 40 to be conveyed in the vertical conveying path 64.
Here, the fiber discharged from the head 31 flies in a spinning space S (refer to
Accordingly, in order to surely deposit the fiber on the base material 40 to form a fiber film, it is necessary to control spread of flight of the fiber, and to induce the flying fiber onto the base material 40. In addition, the spinning space S in
Meanwhile, the head 31 to be used in the apparatus 10 has a control body 312a described later. The control body 312a suppresses spread of flight of the fiber, and controls induction of the fiber to the base material 40.
Accordingly, according to the present embodiment, though having a simple configuration, the apparatus 10 suppresses spread of the flying fiber, and controls induction of the fiber to the base material. Thereby the apparatus 10 can improve quality and productivity of the fiber film, and consequently can reduce an apparatus cost. In addition, in the following description, it is sometimes called simply flight control of the fiber to suppress spread of the flying fiber and control induction of the fiber to the base material.
Next, respective portions of the apparatus 10 will be described in detail, with reference to
To begin with, the power source 20 will be described. The power source 20 is connected to the respective heads 31 of the head unit 30 described later. In order to charge the raw material liquid to be fed to each of the heads 31, the power source 20 applies a voltage of 30-50 kV for example to the head 31.
In addition, the power source 20 is connected to the control body 312a described later of each of the heads 31. The power source 20 applies a voltage to the control body 312a for flight control of the fiber. The voltage to be applied to the control body 312a has the same polarity and the same value as those of the voltage to be applied to the head 31, for example.
In the present embodiment, the power source 20 is used commonly as the power source for applying the voltage to the head 31, and the power source for applying the voltage to the control body 312a, but a power source for the head 31 and a power source for the control body 312a may be separate power sources, respectively.
Next, the head unit 30 will be described. The head units 30 are respectively arranged at the both sides of the vertical conveying path 64 to convey the base material 40 in the Y direction of
The head unit 30 includes one or more heads 31. In the present embodiment, the head unit 30 includes the three heads 31, for example, as shown in
In addition, in the present embodiment, the apparatus 10 has the three vertical conveying paths 64 as shown in
In addition, the three heads 31 of the head unit 30 are supported by the support 50, as shown in
In addition, intervals d2 (refer to
In addition, the respective heads 31 are connected to a raw material liquid storage tank not shown, via a liquid feeding mechanism not shown. The raw material liquid is a solution in which a raw material of the fiber is dissolved in a solvent at a prescribed concentration.
The raw material of the fiber is not particularly limited, and can be changed arbitrarily in accordance with the material of the fiber film to be formed. As the raw material of the fiber, a polyolefin system resin, a thermoplastic resin, a thermosetting resin, and so on are quoted, for example. As a specific example, the raw material can be formed by one kind of polymer or mixed spinning of two or more kinds of polymers selected from the group consisting of polystyrene, polycarbonate, polymethyl methacrylate, polypropylene, polyethylene, polyethylene terephthalate, polybutylene terephthalate, polyamide, polyoxymethylene, polyamide-imide, polyimide, polysulfone, polyethersulfone, polyetherimide, polyether ketone, polyphenylene sulfide, modified polyphenylene ether, syndiotactic polystyrene, liquid crystal polymer, that are thermoplastic resins, a urea resin, unsaturated polyester, a phenol resin, a melamine resin, an epoxy resin that are thermosetting resins, and a copolymer containing these, and so on. In addition, the raw material of the fiber which can be applied to the present embodiment is not limited to the listed raw materials. The listed raw materials of the fiber are just exemplified.
The solvent may be used as long as it can dissolve the raw material of the fiber. The solvent can be changed arbitrarily in accordance with the raw material of the fiber to be dissolved. As the solvent, a volatile organic solvent such as an alcohol system solvent and an aromatic system solvent, or water can be used. As the organic solvent, specifically, isopropanol, ethylene glycol, cyclohexanone, dimethylformamide, acetone, ethyl acetate, dimethylacetamide, N-methyl-2-pyrolidone, hexane, toluene, xylene, methyl ethyl ketone, diethyl ketone, butyl acetate, tetrahydrofuran, dioxane, pyridine, and so on are quoted, for example. In addition, the solvent may be one kind of solvent, or mixture of plural kinds of solvents, selected from the listed solvents. In addition, the solvent which can be applied to the present embodiment is not limited to the listed solvents. The listed solvents are just exemplified.
With the above-described configuration, the head units 30 discharge the charged raw material liquids from the heads 31 described later to simultaneously form the fiber films on the both surfaces of the base material 40 to be conveyed in the vertical conveying path 64, respectively.
That is, to begin with, the raw material liquid is fed to each of the heads 31 of the head unit 30 from the raw material liquid storage tank via the liquid feeding mechanism. In addition, the voltage is applied to the head 31 by the power source 20.
The head 31 discharges the charged raw material liquid toward one surface of the base material 40 to be conveyed in the vertical conveying path 64. The solvent in the raw material liquid which has been discharged from the head 31 volatilizes in the atmosphere in the apparatus 10.
The raw material (fiber) in the raw material liquid which has been discharged from the head 31 flies and reaches the one surface of the base material 40 to be conveyed in the vertical conveying path 64, and thereby the fiber film is formed on each of the both surfaces of the base material 40.
In addition, a part of the fiber which has been discharged from the head 31 tries to fly also in the width direction (the Z direction of
Next, the unwinding reel 41 and the winding reel 42 will be described. The unwinding reel 41 and the winding reel 42 are rotated by a drive source not shown. The unwinding reel 41 feeds the base material 40 into a chassis 13, via an inlet port 11 of the chassis 13 of the apparatus 10 (refer to an arrow A of
The base material 40 which has been fed in the apparatus 10 is extended among a plurality of rollers 61 of the conveying device 60, and thereby is conveyed via the vertical conveying path 64.
After having been formed with the fiber films by the head units 30 arranged in the vertical conveying paths 64, the base material 40 is discharged outside the apparatus 10 from the outlet port 12 (refer to the arrow B of
Next, the support 50 will be described. As shown in FIG. 2, the support 50 supports the head unit 30 opposite to the base material 40 to be conveyed in one vertical conveying path 64, and the head unit 30 opposite to the base material 40 to be conveyed in the other vertical conveying path 64.
Next, the conveying device 60 will be described. In order to convey the base material 40, the conveying device 60 has a plurality of the rollers 61 and the drive source 62 (refer to
The plurality of rollers 61 are arranged at the prescribed positions in the apparatus 10 and support the base material 40, to form a plurality of horizontal conveying paths 63 to convey the base material 40 in the X1 direction, and a plurality of the vertical conveying paths 64 to convey the base material 40 in the Y direction.
In order to feed the base material 40 to the vertical conveying path 64, and convey the base material 40 which has passed through the vertical conveying path 64 and has been formed with the fiber film to the next vertical conveying path 64 or outside the apparatus 10, each of the horizontal conveying paths 63 is connected to the both end portions in the Y direction of the vertical conveying paths 64.
In the present embodiment, the four horizontal conveying paths 63 are formed by the rollers 61, as shown in
In addition, the horizontal conveying paths 63 include two conveying paths each of which conveys the base material 40 that has passed through the one vertical conveying path 64 to the next vertical conveying path 64.
Further, the horizontal conveying paths 63 include one conveying path to convey the base material 40 which has passed through the last vertical conveying path 64 to the outlet port 12.
In the present embodiment, the first horizontal conveying path 63 which conveys the base material 40 to be fed from the inlet port 11 connects to the lower end portion (the end portion in the Y2 direction of
In addition, in the present embodiment, the three vertical conveying paths 64 are formed by the rollers 61, as shown in
Accordingly, the first vertical conveying path 64 conveys the base material 40 toward the Y1 direction. The next vertical conveying path 64 conveys the base material 40 toward the Y2 direction, and the further next vertical conveying path 64 changes the direction thereof to the Y1 direction and conveys the base material 40 toward the Y1 direction.
In addition, the number of the vertical conveying paths 64, the number of the horizontal conveying paths 63 and the number of the rollers 61 are not limited to the numbers of the present embodiment, respectively.
The drive source 62 has a motor to rotate a plurality of the rollers 61. The drive source 62 may have a plurality of motors for rotating a plurality of the rollers 61, respectively, or may have one common motor.
In addition, the electrospinning apparatus of the present embodiment is not limited to the apparatus 10, but according to the apparatus 10, it is possible to provide a plurality of the vertical conveying paths 64 of the base material 40 on which the fiber is to be discharged, in a limited space of the apparatus, as described above. Further, it is possible to simultaneously form the fiber films respectively on the both surface of the base material 40, in the vertical conveying path 64. Accordingly, it is possible to miniaturize the apparatus 10, and also it is possible to improve a forming speed of the fiber film.
Next, a plurality of the heads 31 included in the head unit 30 will be described in detail, with reference to
As shown in
The number of the nozzle units 311 can be changed arbitrarily in accordance with a width of the base material 40, and so on. The head 31 shown in
Each of the nozzle units 311 has a nozzle 311a, a mounting body 311b, and a main body 311c.
To begin with, the nozzle 311a will be described below. The nozzle 311a is conductive and is resistant to the raw material liquid. The nozzle 311a has a needle-like shape extending in a direction facing the base material 40, for example. The nozzles 311a are arranged in parallel when seen from the Y direction, and in a line in the Z direction with a pitch p (refer to
The nozzle 311a has an opening for discharging the raw material liquid (fiber) toward the base material 40 at one end (hereinafter, sometimes called a tip) facing the base material 40. The nozzle 311a has a space that is a flow path of the raw material liquid not shown inside thereof. The nozzle 311a is mounted on the mounting body 311b at the other end. The nozzle 311a is connected to the power source 20 via the mounting body 311b and the main body 311c, and is applied with a voltage.
In addition, the shape of the nozzle 311a is not limited to a needle-like shape, but it is made to have a needle-like shape, and thereby electric field concentration becomes easy to occur at the tip of the nozzle 311a. When the electric field concentration occurs at the tip of the nozzle 311a, it is possible to enhance a strength of the electric field occurring between the nozzle 311a and the base material 40. Accordingly, it is possible to lower the voltage to be applied by the power source 20.
In addition, the tip of the nozzle 311a is sharpened, and thereby the electric field strength at the tip of the nozzle 311a can be concentrated, and accordingly, the nozzle 311a may have a cone shape with a sharp tip, for example.
The mounting body 311b will be described below. The mounting body 311b is detachably mounted on the main body 311c at a side opposite to a side on which the nozzle 311a is mounted, for example (refer to
The main body 311c will be described below. The main body 311c is conductive and is resistant to the raw material liquid. The main body 311c has four side surfaces extending in the Z direction (the width direction of the base material 40) as shown in
The main body 311c is fixed to a mounting portion not shown so that one side surface 311x out of the four side surfaces faces the base material 40. The nozzle 311a is mounted on the side surface 311x via the mounting body 311b.
The main body 311c has a space that is a flow path of the raw material liquid not shown inside thereof. The flow path inside the main body 311c communicates with the flow path inside the mounting body 311b. In addition, the raw material liquid is fed to the flow path inside the main body 311c via the liquid feeding mechanism.
In addition, the main body 311c of the present embodiment is commonly used as the main bodies of a plurality of the nozzle units 311, but a plurality of the main bodies 311c may be provided respectively for a plurality of the nozzle units 311.
In addition, the side surface of the main body 311c on which a plurality of the nozzles 311a are arranged is not limited to one side surface thereof. For example, a plurality of the nozzles 311a may be arranged on each of the two different side surfaces of the main body 311c. In this case, the main body 311c is fixed to a mounting portion not shown so that the two side surfaces thereof face the base material 40 side.
In addition, the shape of the main body 311c may be a polygonal prism other than a quadrangular prism. Hereinafter, the head 31 in which the nozzles 311a are arranged on each of two side surfaces 311y, 311z of the main body 311c having a shape of a polygonal prism other than a quadrangular prism will be described, with reference to
The nozzles 311a are arranged in a line in the Z direction in each of the side surface 311y, 311z of the main body 311c. That is, the head 31 has a total of two nozzle lines.
Hereinafter, a plurality of the nozzles 311a to be arranged on the side surface 311y is sometimes called a first nozzle line 313. In addition, a plurality of the nozzles 311a to be arranged on the side surface 311z is sometimes called a second nozzle line 314. In addition, the nozzles 311a which belong to the first nozzle line 313 are sometimes called first nozzles 313a. Further, the nozzles 311a which belong to the second nozzle line 314 are sometimes called second nozzles 314a.
Positions of a plurality of the first nozzles 313a belonging to the first nozzle line 313 and positions of a plurality of the second nozzles 314a belonging to the second nozzle line 314 are respectively different in the Z direction as shown in
For example, a plurality of the first nozzles 313a belonging to the first nozzle line 313 and a plurality of the second nozzles 314a belonging to the second nozzle line 314 can be arranged respectively at positions deviated from each other by ½ pitch (p/2) as shown in
The positions of the first nozzles 313a and the second nozzles 314a are deviated in this manner, and thereby the fiber to be formed by the raw material liquid to be discharged from the second nozzle 314a belonging to the second nozzle line 314 can be deposited, between an area in the base material 40 on which the fiber is to be deposited by the raw material liquid to be discharged from the one first nozzle 313a belonging to the first nozzle line 313, and an area in the base material 40 on which the fiber is to be deposited by the raw material liquid to be discharged from the first nozzle 313a adjacent to the relevant one first nozzle 313a.
Accordingly, even when the pitch p of a plurality of the first nozzles 313a in the first nozzle line 313 and the pitch p of a plurality of the second nozzles 314a in the second nozzle line 314 are made longer, it is possible to suppress occurrence of unevenness in the fiber film to be formed on the base material 40. In addition, this means that an apparent pitch of a plurality of nozzles 311a in the Z direction is shortened. Accordingly, compared with a case in which the same number of nozzles 311a are arranged in a line, in this case, it is possible to make the length of the main body 311c shorter, and accordingly, it is possible to achieve miniaturization of the head 31.
Since the pitch p of a plurality of the first nozzles 313a in the first nozzle line 313 and the pitch p of a plurality of the second nozzles 314a in the second nozzle line 314 can be made longer, it is possible to suppress electric field interference between the tips of a plurality of the first nozzles 313a in the first nozzle line 313, and electric field interference between the tips of a plurality of the second nozzles 314a in the second nozzle line 314. Further, it is possible to suppress electric field interference between the tip of the first nozzle 313a belonging to the first nozzle line 313, and the tip of the second nozzle 314a belonging to the second nozzle line 314. As a result, it is possible to stabilize formation of the fiber film on the base material 40.
In addition, as shown in
In addition, as shown in
However, as shown in
In addition, as shown in
In addition, as shown in
The first nozzle line 313 and the second nozzle line 314 are configured as described above, and thereby the above-described distance d5 when seen from the Z direction can be made longer than a case in which a plurality of the first nozzle 313a belonging to the first nozzle line 313, and a plurality of the second nozzles 314a belonging to the second nozzle line 314 are arranged in parallel with each other.
Accordingly, it is possible to suppress occurrence of electric field interference between the tips of a plurality of the first nozzles 313a belonging to the first nozzle line 313, and the tips of a plurality of the second nozzles 314a belonging to the second nozzle line 314. As a result, it is possible to stabilize formation of the fiber film on the base material 40.
It is preferable that an angle θ1 (refer to
In addition, a distance d7 (refer to
The main body 311c shown in
The cross section shape of the main body 311c shown in
In addition, an angle formed by the side surface 311y and the side surface 311z is θ2, the above-described angle θ1 can be expressed by the following expression.
θ1=180°−θ2
In addition, the nozzle 311a shown in
Next, the electric field control unit 312 will be described, with reference to
To begin with, the control body 312a will be described below. The control body 312a is conductive and is resistant to the raw material liquid. The control body 312a is mounted on one end of the connecting body 312b. In addition, the connecting body 312b is mounted on the main body 311c of the nozzle unit 311, as described later. In addition, the main body 311c is connected to the power source 20 as described above.
Accordingly, the control body 312a is applied with the voltage having the same polarity and the same value as those of the voltage to be applied to nozzle 311a by the power source 20, via the main body 311c and the connecting body 312b.
In addition, the control bodies 312a are mounted on the connecting bodies 312b, and thereby the control bodies 312a are arranged at the both ends in the Z direction of the head 31 (refer to
That is, the control body 312a is arranged in the vicinity of the outermost nozzle unit 311 out of a plurality of the nozzle units 311 arranged in the Z direction. Specifically, the control body 312a is arranged adjacent to the nozzle 311a included in the outermost nozzle unit 311 with an interval d3 (refer to
It is preferable that the interval d3 is not less than the pitch p of the respective nozzles 311a. When the interval d3 becomes narrower than the pitch p, electric field interference occurs between the control body 312a and the nozzle 311a.
Further, the control body 312a is arranged so as to extend in the outside direction of the spinning space S (refer to
The direction in which the control body 312a extends toward the outside of the spinning space S is substantially orthogonal to the direction (refer to the X direction in
In addition, when the control body 312 is nearer to the base material 40 than the tip of the nozzle 311a, a possibility of breakdown occurs. Accordingly, the control body 312a is mounted on the connecting body 312b, and thereby the control body 312a is arranged to have a height h (≥0) from the tip of the nozzle 311a (refer to
The control body 312a has a length L (for example, refer to
The control body 312a has a width W in the direction orthogonal to the direction of the length L (refer to
Hereinafter, the connecting body 312b will be described. The connecting body 312b is a plate-like member, for example, and is conductive and is resistant to the raw material liquid. The connecting bodies 312b are mounted on the both ends of the main body 311c of the nozzle unit 311, at the other end sides opposite to one ends on which the control bodies 312a are mounted. The connecting bodies 312b are mounted on the main body 311c, and thereby the control bodies 312a are arranged at the above-described positions and in the above-described directions.
In addition, the connecting body 312b electrically connects the main body 311c of the nozzle unit 311 and the control body 312a. Accordingly, the power source 20 to apply the voltage to the nozzle unit 311 can be commonly used as a power source to apply the voltage to the control body 312a.
In addition, a support for arranging the control body 312a as described above may be provided, in place of the control body 312b. In addition, a terminal for applying the voltage to the control body 312a may be provided, in place of the connecting body 312b.
In addition, it is not necessary that the control body 312a and the connecting body 312b are separate members. For example, the control body 312a and the connecting body 312b may be formed by binding an identical member.
Hereinafter, flight control of the fiber by the control body 312a of the control unit 312 will be described.
With the above-described configuration, the control body 312a of the control unit 312 is applied with the voltage by the power source 20, and thereby the control body 312a makes an electric field to be generated at the periphery of each of the both end portions of the head 31 (at the peripheries of the outermost nozzle units 311).
As described above, the fiber to be discharged from the head 31 flies in the direction of the base material 40 to be conveyed in the vertical conveying path 64, and also tries to fly in the width direction (refer to the Z direction of
In contrast, the control body 312a makes the electric field to be generated at the periphery of each of the both end portions of the head 31, and thereby the control body 312a suppresses spread of flight of the fiber to be discharged from the head 31 (the nozzle 311a) in the width direction of the base material 40, and controls the fiber so as to be induced to the base material 40.
Specifically, the control body 312a suppresses flight of the fiber to the outside (the Z direction side) from the spinning space S between the head 31 and the base material 40 in
The flight control of the fiber by the control body 312a will be specifically described, with reference to
It can be confirmed that compared with the distributions of the equipotential lines Q in the spinning space S in
In addition, it can be confirmed, from central orbits O of the flying fibers estimated from the equipotential lines Q, that compared with the cases of
Next, a control configuration of the apparatus 10 will be described, with reference to
As shown in
The control device 80 includes a processor 81 and a memory 82. The processor 81 includes a CPU, or an MPU, for example. The memory 82 includes a ROM 82a and a RAM 82b, for example.
The processor 81 controls the whole operation of the apparatus 10. The ROM 82a stores a control program and so on for a control operation by the processor 81, for example. The RAM 82b provides a work area for developing the control program and so on read from the ROM 82a, for example.
For example, the processor 81 reads the control program stored in the ROM 82a, and develops the control program in the RAM 82b. The processor 81 controls the power source 20 and the liquid feeding mechanism not shown, and so on, in accordance with the control program, in order to make the raw material liquid to be discharged from the head unit 30.
In addition, the processor 81 controls the drive source 62, in accordance with the control program, in order to convey the base material 40. Further, the processor 81 controls the power source 20, in accordance with the control program, in order to apply the voltage to the control body 312a.
As described above, the head 31 according to the embodiment has the control body 312a which is arranged in the vicinity of the outermost nozzle unit 311 in the width direction of the base material 40, and extends toward the outside of the spinning space S between the nozzle unit 311 and the base material 40. The control body 312a is applied with the voltage of the same polarity as the voltage to be applied to the nozzle unit 311, and thereby makes the electric field to be generated at the periphery of the end portion of the head 31 (at the periphery of the outermost nozzle unit 311). According to the head 31 according to the embodiment, spread of flight of the fiber to be discharged from the nozzle unit 311 can be suppressed, and the induction of the fiber to the base material 40 can be controlled, by the control body 312a.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
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