KR101586733B1 - Electrospinning devices of manufacture for nano fiber - Google Patents

Abstract

According to the present invention, hot melt is sprayed onto a base material in a nozzle block of a unit located at the front end, and a polymer spinning solution is sprayed onto a base material in a nozzle block of a unit positioned at the rear end to laminate the nanofibers, The present invention relates to an electrospinning device for manufacturing nanofibers capable of preventing the formation of nanofibers in a solution main tank. The electrospinning device includes at least one solution main tank filled with hot melt, A hot melt unit having a nozzle block in which a plurality of nozzle-shaped nozzles in the longitudinal direction are provided in order to inject hot-melt into the nozzle blocks, the nozzle blocks being arranged at both ends thereof; At least one solution main tank filled with a spinning solution and a polymer spinning solution filled in the solution main tank are sprayed with a polymer spinning solution on a substrate provided inside the case to emit the spinning solution for spinning, A spinning solution unit having a nozzle block in which a plurality of nozzle tubes having a plurality of fin-shaped nozzles in the longitudinal direction are arranged; A collector disposed in each unit and spaced apart from the nozzle by a predetermined distance in order to collect the hot melt and the polymer solution for spraying from nozzles provided in the nozzle block; A voltage generating device for generating a voltage in the collector; And an auxiliary transfer device for transferring the substrate; And a plurality of hot melt units and spinning solution units are provided, and the hot melt units and the spinning solution units are alternately installed.

Description

TECHNICAL FIELD [0001] The present invention relates to an electrospinning device for manufacturing nanofibers,

The present invention relates to an electrospinning apparatus, and more particularly, to an electrospinning apparatus, more particularly, to an electrospinning apparatus which comprises a plurality of units provided at an end of a nozzle block, The present invention relates to an electrospinning device for manufacturing nanofibers that facilitates adhesion between a substrate and a nanofiber web during electrospinning of a polymer spinning solution in a nozzle block of a unit.

Generally, a filter is classified as a liquid filter and an air filter as a filtration device for filtering foreign matters in a fluid.

Among the filters described above, the air filter has been developed in order to prevent the deterioration of high-tech products along with the development of high-tech industries, semiconductor manufacturing that removes biologically harmful substances such as particulates such as dusts, microparticles such as bacteria and fungi, bacteria, Assembly, hospitals, food processing plants, agriculture, forestry and fisheries. In addition, filters are widely used in workplaces where large amounts of dust are generated, thermal power plants, and the like.

On the other hand, a gas turbine used in a thermal power plant sucks and compresses purified air from the outside, injects the compressed air into the combustor together with the fuel, mixes the mixed air and fuel, and generates high temperature and high pressure combustion gas And is then injected into the vanes of the turbine to obtain rotational power.

Because these gas turbines are made up of very precise components, they are periodically serviced and use a pre-treatment air filter to purify the air in the air entering the compressor.

Here, the air filter is capable of supplying purified air by preventing foreign substances such as dust and dust contained in the air from penetrating into the filter media when the combustion air sucked into the gas turbine is taken in the air.

However, in the case of the above-described air filter, particles having a large foreign particle accumulate on the surface of the filter filter material to form a filter cake on the filter filter material surface, and fine particles are accumulated in the filter filter material, Thereby preventing the pores of the membrane.

Thus, when the particles are accumulated on the surface of the filter media, there is a problem that the pressure loss of the filter is increased and the service life is shortened.

 On the other hand, existing air filters use the principle that static electricity is applied to the fibrous aggregate constituting the filter medium and the particles are collected in the filter medium by the electrostatic force. In order to eliminate the filter efficiency due to the electrostatic effect, In accordance with EN779, which is an air filter classification standard of the present invention, the electrostatic effect is excluded and the efficiency is measured. As a result, the actual efficiency of the filter is lowered by 20% or more.

In order to solve the above-mentioned problems, various types of filter media have been developed and used, such as manufacturing nanofiber fibers and applying the nanofibers to filters.

When the nanofibers are applied to the filter, the specific surface area is larger than that of the conventional filter media having a large diameter, and the flexibility of the surface functional groups is also good. In addition, by having the processing size of nano gold, it is possible to efficiently filter fine dust particles.

In this case, when the filter is manufactured using nano-sized fibers, there is a problem that the production cost is increased. As a result, there is a problem that it is difficult to produce and distribute the filter using nano- It is difficult to control the conditions for manufacturing and production of the filter, and thus it is difficult to mass-produce the filter.

In addition, in the case of a technique for spinning conventional nanofibers, since it is limited to a small-scale working line focused on a laboratory, there is a demand for a technique of spinning nanofibers by dividing a spinning zone and using a unit concept.

On the other hand, in the conventional electrospinning device, a spinning solution is electrospun on one surface of a substrate supplied from the outside to form a nanofiber web, thereby producing a nanofiber. That is, the conventional electrospinning device is composed of a bottom-up or top-down electrospinning device, and electrospun spinning solution is applied only to the lower surface or the upper surface of the substrate supplied into the electrospinning device to form a nanofiber web.

As described above, since the electrospinning device is composed of the bottom-up electrospinning device or the top-down electrospinning device, the spinning solution is electrospun on the lower surface or the upper surface of the base material supplied from the outside and conveyed in a predetermined direction, The nanofiber or nanofiber filter formed can be produced.

However, when the polymeric spinning solution is electrospun on the substrate through the bottom-up electrospinning device or the top-down electrospinning device to form a laminate of nanofiber webs, the nanofiber web may be removed from the substrate during transfer of the substrate, There is a problem that the nanofiber web is dislodged from the substrate of a product made of a fiber filter.

That is, when the nanofiber web is laminated by electrospinning the polymer spinning solution on the base material through the electrospinning device, the product made of the nanofiber or the nanofiber filter is used as the material of the base and the polymer spinning solution The nanofiber web on which the polymer spinning solution is electrospun and laminated is desorbed from the substrate due to the difference in the components.

Meanwhile, a laminating process for laminating the base material and the nanofiber web to be pressed in the nanofiber or nanofiber filter manufactured through the electrospinning device is provided as a post-process. However, since the material and the composition of the base and the polymer solution are different The nanofiber web on which the polymer spinning solution is electrospun and laminated is desorbed from the substrate.

In order to solve the problems described above, the polymer spinning solution and the hot melt are mixed and supplied to the nozzle block of the electrospinning device when the polymer spinning solution is supplied, so that the polymer spinning solution is injected simultaneously with the polymer spinning solution during the electrospinning of the polymer spinning solution A configuration in which the base material and the polymer spinning solution are electrified by the hot melt to prevent desorption of the nanofiber web is proposed. However, when the polymer spinning solution and the hot melt are mixed and the hot melt is mixed with the polymer melt There is a problem that the hot melt is radiated to the portion and the portion where the hot melt is not required because the use liquid is radiated, and the performance and the quality of the nanofiber or nanofiber filter are lowered.

Further, the use amount of the hot melt is increased by mixing hot melt in the polymer spinning solution, and the performance and quality of the nanofiber web, which is laminated by electrospinning of the polymer spinning solution on the substrate upon mixing and adding an excessive amount of hot melt to the polymer spinning solution And the like.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-described problems, and it is an object of the present invention to provide a nozzle block of a unit positioned at a tip end of a plurality of units in an electrospinning apparatus, An object of the present invention is to provide an electrospinning device for manufacturing nanofibers which facilitates adhesion of a nanofiber web to a substrate by electrospinning a polymer spinning solution on a substrate onto which hot melt is sprayed, thereby laminating the nanofiber web.

In the present invention, a plurality of units of the electrospinning apparatus are sequentially provided, and a unit for spraying the hot melt and a unit for injecting the polymer solution are alternately arranged, and the unit for spraying the hot melt includes a plurality of nozzles, The nozzle tubes provided in the longitudinal direction (running direction) are provided only at both ends of the nozzle block, and hot melts are injected only at the nozzles of the nozzle tubes installed at both ends of the nozzle block, And an electrospinning device for producing nanofibers capable of preventing the nanofiber web from being separated from the substrate.

The present invention can be applied to both the bottom-up electrospinning device and the bottom-up electrospinning device, in which hot melts are separately injected and injected only at both ends in the width direction of the substrate, It is possible not only to spray the hot melt onto the base material through each unit but also to emit the same or different kind of polymer spinning solution on the base material, And an electrospinning device for producing nanofibers capable of producing a nanofiber filter and capable of mass production.

According to an aspect of the present invention, there is provided an electrospinning device for manufacturing nanofibers, comprising: at least one solution main tank filled with hot melts; A hot melt nozzle having a nozzle block in which a plurality of nozzle-shaped nozzles having pin-shaped nozzles arranged in the longitudinal direction (running direction) of the substrate are arranged at both end portions of the nozzle block, unit; At least one solution main tank filled with a spinning solution and a polymer spinning solution filled in the solution main tank are sprayed with a polymer spinning solution on a substrate provided inside the case to emit the spinning solution for spinning, A spinning solution unit having a nozzle block having a plurality of nozzle tubes arranged in the width direction of the nozzle block, the nozzle tubes having a plurality of pin-shaped nozzles arranged in the longitudinal direction of the substrate (longitudinal direction); A collector disposed in each unit and spaced apart from the nozzle by a predetermined distance in order to collect the hot melt and the polymer solution for spraying from nozzles provided in the nozzle block; A voltage generating device for generating a voltage in the collector; And an auxiliary transfer device for transferring the substrate; And a plurality of hot melt units and spinning solution units are provided, and the hot melt units and the spinning solution units are alternately installed.

Here, a waste liquid recovery path for recovering the hot melt and polymer solution for overflowing in the nozzle block of each unit, a recovery tank for storing the recovered hot melt and the polymer solution for use in connection with the waste liquid recovery path, And an intermediate tank through which the hot melt and the polymer solution are fed respectively to the solution main tank and the transfer tank, wherein the hot melt and the polymer solution are supplied to the nozzle block from the intermediate tank through the supply pipe; As shown in FIG.

A condensing device for condensing and liquefying the VOC generated in each unit, a distillation device for distilling and liquefying the condensed and liquefied VOC through the condensing device, and a storage device for storing the liquefied solvent in the distillation device A VOC recycling apparatus for reusing and recycling a solvent in a storage tank in which a VOC distilled and liquefied in a distillation apparatus is classified and stored as a polymer spinning solution; As shown in FIG.

On the other hand, the case has an upper portion made of an insulator and a lower portion made of a conductor, and the upper and lower portions of the case are mutually coupled.

In addition, the thickness of the nanofiber web which is provided at the rear end of the spinning solution unit and injected onto the substrate conveyed by ultrasonic waves is measured, and the feeding speed of the substrate and the voltage A thickness measuring device for adjusting the thickness of the nanofiber web by adjusting the intensity; As shown in FIG.

On the other hand, by measuring the air permeability of the nanofiber web that is provided at the last stage of each unit and ejected onto the substrate by ultrasonic waves, and controlling the feed speed of the substrate and the voltage intensity of the voltage generator according to the measured degree of air permeability of the nanofiber web An air permeability measuring device for controlling the air permeability of the nanofiber web; As shown in FIG.

A pair of support rollers for supporting the base material on the buffer zone and a pair of support rollers are provided so as to be movable up and down between the pair of support rollers to wind the base material A substrate conveyance speed regulating device including at least one regulating roller for regulating a conveyance speed of the substrate by vertical movement of each regulating roller; As shown in FIG.

At this time, a temperature regulation controller which is spirally formed on the periphery of each nozzle tube body of the nozzle block, and which is formed in a hot wire shape and controls the temperature of the hot melt and the polymer solution to be supplied into the nozzle tube body; .

Here, the hot melt injected from the nozzle tubes at both ends of the nozzle block of the hot melt unit is injected only at both ends in the width direction of the substrate to be transferred.

On the other hand, after the hot melt is sprayed from the nozzle provided in the nozzle tube of the hot melt unit, and the substrate to which the hot melt is sprayed is supplied to the spinning solution unit located at the rear end, the polymer spinning solution is supplied from the nozzle provided in the nozzle tube of the spinning solution unit And the process of lamination and formation of the nanofiber web is alternately repeated.

As described above, according to the present invention having the above-described structure, hot melt is sprayed from a nozzle block of a unit located at a tip end among a plurality of units provided in an electrospinning apparatus, The nanofiber web can be easily adhered on the substrate by alternately spraying the hot melt and the polymer spinning solution such as electrospinning the use solution and hot melt is applied only to both widthwise ends of the substrate to be transported by spraying the hot melt only at both end portions of the nozzle block And it is possible to prevent the separation of the nanofiber web from the substrate.

In addition, the present invention can reduce the use of hot melt by spraying hot melt only on both ends in the width direction of the substrate, and the hot melt is sprayed only on both ends in the width direction of the substrate, The reliability of the product can be improved and the performance and quality of the nanofiber or nanofiber filter can be improved.

The present invention can be applied to both the bottom-up electrospinning device and the top-down electrospinning device, and it is possible to not only spray the hotmelt onto the substrate through each unit, but also to electrospray the same or different kinds of polymer- It is possible to produce nanofibers and nanofiber filters of various materials and kinds, and it is possible to mass-produce nanofibers or nanofiber filters of materials and shapes required in the field.

1 is a side view schematically showing an electrospinning apparatus according to the present invention,
Fig. 2 is a perspective view schematically showing a nozzle block provided in each unit of the electrospinning apparatus according to the present invention,
Fig. 3 is a plan view schematically showing a nozzle block provided in each unit of the electrospinning apparatus according to the present invention,
4 is a plan view schematically showing a nozzle block installed in each unit of the electrospinning device according to the present invention for electrospinning the polymer spinning solution,
5 is a front sectional view schematically showing a state in which an electric heater is installed in a nozzle block installed in each unit of the electrospinning apparatus according to the present invention,
6 is a sectional view taken along line A-A '
7 is a view schematically showing an auxiliary transfer device of an electrospinning device according to the present invention,
8 is a view schematically showing another embodiment of the auxiliary belt roller of the auxiliary transfer device according to the present embodiment,
FIG. 9 to FIG. 10 are plan views schematically showing an operation process in which a hot melt and a polymer solution are sequentially injected through a nozzle block installed in each unit of the electrospinning device according to the present invention,
11 to 14 are side views schematically showing an operation process of the substrate conveyance speed adjusting apparatus of the electrospinning apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the scope of the present invention, but is merely an example, and various modifications can be made without departing from the technical spirit of the present invention.

2 is a perspective view schematically showing a nozzle block installed in each unit of the electrospinning apparatus according to the present invention for spraying hot melt. Fig. 3 is a cross- FIG. 4 is a cross-sectional view schematically showing a nozzle block provided in each unit of the electrospinning apparatus according to the present invention and for spraying hot melt. Fig. 5 is a front sectional view schematically showing a state in which an electric heater is installed in a nozzle block installed in each unit of the electrospinning apparatus according to the present invention, Fig. 6 is a sectional view taken on line A-A ' Fig. 7 is a view schematically showing an auxiliary feeding device of an electrospinning apparatus according to the present invention, and Fig. 9 to 10 are diagrams showing a state in which the hot melt and the polymer spinning solution are sequentially injected through the nozzle block installed in each unit of the electrospinning apparatus according to the present invention, And FIGS. 11 to 14 are side views schematically showing the operation of the apparatus for controlling the substrate transport speed of the electrospinning apparatus according to the present invention.

As shown in the figure, the electrospinning device 1 according to the present invention is composed of a bottom-up electrospinning device, in which at least one unit 10a, 10b, 10c, 10d is sequentially arranged at a predetermined interval, A solution of a polymeric spinning solution or other material of the same material in the upward direction is individually electrospun through the respective units 10a, 10b, 10c, and 10d, or a polymer spinning solution of a different material is electrospun to form nanofibers or nanofiber filters And so on.

In one embodiment of the present invention, the electrospinning device 1 is a bottom-up electrospinning device, but it may also be a top-down electrospinning device (not shown).

In the embodiment of the present invention, four units 10a, 10b, 10c and 10d of the electrospinning device 1 are provided, but the number of the units 10a, 10b, 10c and 10d is two Or more, but is not limited thereto.

Each of the units 10a, 10b, 10c and 10d of the electrospinning device 1 has a solution main tank 8 in which a hot melt or a polymer solution is filled, (Not shown) for supplying a hot melt or polymer spinning solution filled in the solution main tank 8 in a fixed amount, and a nozzle 12 made of a fin type, for spraying hot melt or polymer spinning solution filled in each of the solution main tanks 8 A nozzle block 11 in which a plurality of nozzle tubes 40 are arranged in the longitudinal direction of the base material 15 and a nozzle for collecting hot melt or polymer spinning solution injected from the nozzle 12 And a voltage generator 14a, 14b, 14c, 14d for generating a voltage in the collector 13. The voltage generator 14a, 14b, 14c, 14d generates a voltage in the collector 13,

The electrospinning device 1 according to the present invention has the structure as described above in which the hot melt or polymer spinning solution filled in each solution main tank 8 is injected into the nozzle tube 40 arranged in the nozzle block 11 through the metering pump The hot melt or polymer spinning solution supplied to the nozzle tube 40 is supplied to the collector 13 having a high voltage through a plurality of nozzles 12 formed in the nozzle tube 40 And hot melt and nanofiber webs are laminated on the substrate 15 transported on the collector 13 to produce nanofibers or nanofiber filters.

The units 10a, 10b, 10c and 10d of the electrospinning device 1 are composed of hot melt units 10a and 10c and spinning solution units 10b and 10d, Hot melt is sprayed from the nozzle block 11a in the nozzle blocks 11a and 10c and the polymer solution is electrospun in the nozzle block 11b in the spraying solution units 10b and 10d positioned at the rear end.

The nozzle blocks 11a in the hot melt units 10a and 10c among the nozzle blocks 11 provided in the respective units 10a to 10d are connected to the solution main tank 8 filled with hot melt , And the nozzle block 11b in the spinning solution units 10b and 10d is connected to the solution main tank 8 filled with the spinning solution.

In an embodiment of the present invention, the nozzle blocks 11 installed in the units 10a, 10b, 10c, and 10d are individually connected to a corresponding number of the solution main tanks 8 to form hot melt or polymer spinning solution The hot melt units 10a and 10c of the respective units 10a to 10d are connected to one solution main tank 8 filled with the hot melt and the spinning liquid unit 10b , 10d may be connected to one solution main tank 8 filled with the polymer solution.

The nozzle blocks 11a provided in the hot melt units 10a and 10c among the nozzle blocks 11 installed in the respective units 10a, 10b, 10c and 10d include a plurality of nozzles 12, The nozzle tube body 40 provided in both longitudinal ends of the nozzle block 11a is arranged only at both ends of the nozzle block 11a and the nozzles of the nozzle tube body 40 arranged at both ends of the nozzle block 11a The hot melt injected from the nozzle block 12 is sprayed onto both widthwise ends of the substrate 15 conveyed on the nozzle block 11a.

The nozzle block 11b disposed in the spinning solution units 10b and 10d of each of the units 10a, 10b, 10c, and 10d to spin-spin the polymer spinning solution onto the substrate 15 includes a plurality of nozzles 12, And a plurality of nozzle tubes 40 arranged in the width direction of the nozzle block are provided in the hot melt units 10a and 10c so that the substrate 15 The nozzle block 11a for spraying the hot melt onto the nozzle body 11a is provided with a plurality of nozzles 12 arranged in the longitudinal direction 9 of the substrate 15 so as to spray hot melt only on both widthwise ends of the substrate 15 40 are arranged on both end portions of the nozzle block.

The nozzle block 11a and the spinning solution units 10b and 10c provided in the hot melt units 10a and 10c among the nozzle blocks 11 installed in the respective units 10a, 10b, 10c and 10d of the present invention, The number and arrangement of the nozzle tubes 40 provided in the nozzle blocks 11b provided in the hot melt units 10a and 10d are different from those of the nozzle blocks 11b provided in the hot melt units 10a and 10c. And 10d, it is also possible to provide the nozzle tube 4 having the same structure and arrangement.

At this time, only the nozzle 12 of the nozzle tube body 40 provided at both ends of the nozzle tube body 40 of the nozzle block 11a installed in the hot melt unit 10a, And the hot melt may be sprayed to both end portions.

When the nozzle block body 11a for spraying the hot melt and the nozzle block 11b for electrospinning the polymer spinning solution are provided with the nozzle tube body 40 having the same structure and arrangement, the nozzle block 11a for spraying the hot melt, The nozzle tube body 40 provided in the nozzle block 11b for electrospinning the polymer spinning solution can be also controlled by a valve (not shown) (Not shown), respectively.

Therefore, the nozzle tubes 40 of the nozzle block 11 provided in each of the units 10a, 10b, 10c, and 10d are individually controlled to adjust the position and the like of the hot melt on the substrate 15, It is possible to control and control the injection order of the hot melt and the polymer spinning solution.

In the embodiment of the present invention, the hot melt is sprayed from the nozzle 12 of the nozzle tube 40 provided at both ends of the nozzle block 11a provided in the hot melt unit 10a and 10c, The nozzle block 40 is provided at both ends and the center of the nozzle block 11a and the nozzles 12 of the nozzle tube 40 The hot melt is sprayed onto both ends in the width direction of the base material 15 and the center portion thereof.

The nozzle tube body 40 is provided at both ends and the center of the nozzle block 11a provided in the hot melt unit 10a and 10c in the present embodiment. However, the position and the number of the nozzle tube body 40 are not limited thereto And can be variously changed.

The nozzle 12 of the nozzle body 40 arranged at both end portions of the nozzle block 11a of the hot melt unit 10a of each of the units 10a, 10b, 10c and 10d as described above, The base material 15 to be transferred is ejected and supplied to the spinning liquid unit 10b located at the rear end of the hot melt unit 10a while the hot melt is ejected to both widthwise ends of the spinning liquid unit 10b, The polymer spinning solution is electrospun through the respective nozzles 12 of the nozzle tube body 40 arranged on the base material supplied to the nozzle block 11b in the width direction of the nozzle block 11b to form the nanofiber webs The above process is repeated to produce a nanofiber or nanofiber filter .

In this way, hot melt is first sprayed onto the base material 15 during the electrospinning of the polymer spinning solution on the base material 15, so that the base material 15 and the nanofiber web 15, which is electrospun on the base material 15 and laminated, To minimize the interference with the polymer spinning solution in which the hot melt is ejected by spraying the hot melt to both widthwise ends of the base material 15 and to improve the performance and quality of the nanofiber or nanofiber filter Can be improved.

Here, in the unit 10a in front of the unit 10a located at the foremost end among the units 10a, 10b, 10c and 10d of the electrospinning device 1, the hot melt and the polymer solution are supplied to the electrospinning A feeding roller 3 for feeding a substrate 15 in which nanofiber webs are alternately injected is provided and a hot melt adhesive layer 15 is disposed behind the unit 10d positioned at the rear end of each unit 10a, 10b, 10c, And a winding roller 5 for winding a substrate 15 on which a nanofiber web is laminated.

The substrate 15 to be fed and fed through the feeding roller 3 is fed into each of the units 10a, 10b, 10c and 10d of the electrospinning device 1 to the winding roller 5 side And an auxiliary transfer device (16) for adjusting the transfer speed of the substrate (15).

The main control unit is provided in the electrospinning apparatus 1 and includes a nozzle block 11 installed in each unit 10a, 10b, 10c and 10d, an auxiliary conveying unit 16 And the voltage generating devices 14a, 14b, 14c, and 14d and controls the thickness measuring device 70, the substrate conveying speed adjusting device 30, and the air permeability measuring device 80, which will be described later.

On the other hand, a laminating apparatus 90 for laminating the nanofiber web electrified on the base material 15 through the units 10a, 10b, 10c and 10d of the electrospinning apparatus 1 is provided in each of the units 10a , And a post-process of the nanofiber web provided at the rear end of the unit 10d positioned at the rearmost end of the electrospinning apparatus 10b, 10c, 10d and electrospun through the electrospinning apparatus 1 by the laminating apparatus 90 do.

As described above, the base material 15 in which the polymer spinning solution is electrospun and the nanofiber web is laminated while passing through each unit 10a, 10b, 10c, and 10d of the electrospinning device 1 is a nonwoven fabric, But is not limited thereto.

The material of the polymer solution to be radiated through each of the units 10a, 10b, 10c and 10d of the electrospinning device 1 is not particularly limited. For example, polypropylene (PP), polyethylene terephthalate (PET), polyvinylidene fluoride, nylon, polyvinyl acetate, polymethylmethacrylate, polyacrylonitrile (PAN), polyurethane (PUR), polybutylene terephthalate (PEI), poly (ethylene terephthalate) (PEI), polyvinylidene chloride (PVA), polyvinyl chloride, polyethyleneimine, polyolefin, polylactic acid (PLA), polyvinyl acetate Polypropylene (PP), heat-resistant polymeric materials such as polyamide, polyimide, polyamideimide, poly (meth) acrylate, and poly - phenylene Aromatic polyesters such as polyethylene terephthalate, polyethylene naphthalate and the like, polytetrafluoroethylene, polydiphenoxaphospazene, polyphenylene sulfide, polyphenylene sulfide, polyphenylene sulfide, poly Polyphosphazenes such as bis [2- (2-methoxyethoxy) phosphazene], polyurethane copolymers including polyurethane and polyether urethane, cellulose acetate, cellulose acetate butyrate, cellulose acetate propionate, etc. Of the polymer is preferably used in a commercial manner.

The polymer spinning solution supplied through the nozzles 12 in the units 10b and 10d located at the rear end of each of the units 10a, 10b, 10c and 10d may be made of a synthetic resin material capable of electrospinning, , And the kind of the solvent is not limited as long as it can dissolve the polymer.

For example, methyl, ethyl, propyl, isopropyl, n-butyl, isobutyl, isopropyl, n-butyl, isobutyl, sec-butyl, Isobutyl alcohol, isopropyl alcohol, methyl alcohol, ethanol, aliphatic compounds such as hexane, tetrachlorethylene, acetone, and glycol groups such as propylene glycol, diethylene glycol, isobutyl ketone, methyl ethyl ketone, aliphatic hydroxyl group, m- Ethylene glycol, and halogen compounds such as trichlorethylene, dichloromethane, aromatic compounds toluene, xylene, alicyclic compounds such as cyclohexanone, cyclohexane and esters such as n-butyl acetate, ethyl acetate, aliphatic ether Butyl cellosolve, acetic acid 2-ethoxy ethanol, 2-ethoxy ethanol, amide dimethyl formamide, dimethylacetamide, etc. And, it is possible to use a mixture of a plurality kinds of solvents. The polymer spinning solution preferably contains, but is not limited to, an additive such as a conductivity improver.

Here, an overflow device 200 is provided in the electrospinning device 1. That is, each of the solution main tanks 8, the second transfer pipe 216, the second transfer control device 218, and the intermediate tank (not shown) are connected to the respective units 10a, 10b, 10c and 10d of the electrospinning device 1 220 and a regeneration tank 230 are respectively provided in the overflow device 200.

The overflow device 200 is provided in each unit 10a, 10b, 10c and 10d of the electrospinning device 1 in the embodiment of the present invention. However, each of the units 10a, 10b, 10c and 10d It is also possible that the overflow device 200 is provided in any one of the units 10a to 10d and the remaining units 10b, 10c and 10d are integrally connected to the overflow device 200, The overflow device 200 is provided in each of the hot melt units 10a and 10c for ejecting the hot melt among the units 10a to 10d or the spinning solution units 10b and 10d for electrospinning the polymer spinning solution The overflow device 200 may be provided.

The overflow device 200 is provided in any one of the units 10a, 10b, 10c and 10d of the electrospinning device 1 through which the hot melt is injected, Or a unit 10b in which a polymeric spinning solution in each of the units 10a, 10b, 10c, and 10d is electrospun and a nanofiber web is laminated is formed on the other unit 10b It is also possible that the overflow device 200 is provided and the remaining unit 10d is integrally connected to the overflow device 200. [

The solution main tank 8 provided in the hot melt units 10a and 10c among the respective units 10a to 10c stores the hot melt and the spinning solution units 10b and 10c, 10d) stores the polymer solution for the raw material of the nanofiber or nanofiber filter. A separate stirring device 211 for preventing the separation and coagulation of the hot melt and the polymer solution is provided in the solution main tank 8.

The second transfer pipe 216 includes a pipe (not shown) connected to the solution main tank 8 or the regeneration tank 230 and valves 212, 213 and 214, Or the polymeric spinning solution to the intermediate tank 220 from the solution tank 8 or the regeneration tank 230 in which the polymer spinning solution is filled.

The second conveyance control unit 218 controls the conveyance operation of the second conveyance pipe 216 by controlling the valves 212, 213 and 214 of the second conveyance pipe 216.

The valve 212 controls the transfer of the hot melt or the polymer solution to the intermediate tank 220 from the solution main tank 8 filled with the hot melt or the polymer solution, And the valve 214 controls the transfer of the hot melt or polymer solution to the intermediate tank 220 from the solution tank 8 and the regeneration tank 230, And controls the amount of the usage amount.

As described above, the liquid surface height of the hot melt or polymer solution is measured by the second sensor 222 provided in the intermediate tank 230, which will be described later, under the control of the valves 212, 213 and 214.

The intermediate tank 220 separately stores the hot melt or the polymer solution used for supplying the solution from the solution tank 8 or the regeneration tank 230 filled with the hot melt or the polymer solution for the hot melt, The nozzle block 11a provided in the nozzles 10a and 10c and the nozzle block 11b provided in the spinning liquid units 10b and 10d supply the hot melt and the polymer solution for spraying, And a second sensor 222 for measuring the temperature of the liquid.

Here, the second sensor 222 is preferably a sensor capable of measuring the liquid level of the hot melt or polymer solution, such as an optical sensor or an infrared sensor, but is not limited thereto.

A supply pipe 240 and a supply control valve 242 for supplying hot melt or polymer solution for the nozzle block 11 are provided in the lower part of the intermediate tank 220. The supply control valve 242, The supply of the hot melt or the polymer spinning solution through the supply pipe 240 is controlled.

The regeneration tank 230 is provided therein with a stirring device 231 for separately storing the hot melt or the polymer solution for use recovered by overflow and for preventing the separation and coagulation of the hot melt or polymer solution.

Here, the first sensor 232 is preferably a sensor capable of measuring the liquid level of the hot melt or polymer solution, such as an optical sensor or an infrared sensor, but is not limited thereto.

Meanwhile, the hot melt or polymer solution for overflowing in the nozzle block 11 is separately recovered through the solution recovery path 250 provided in the lower part of the nozzle block 11, and the solution recovery path 250 The polymer spinning solution in the regeneration tank 230 is recovered through the first transfer pipe 251.

The first transfer pipe 251 includes a pipe (not shown) connected to the regeneration tank 230 and a pump (not shown), and the hot melt and the polymer spinning solution are filled with solution To the recovery tank (230) in the recovery path (250).

At this time, it is preferable that the regeneration tank 230 is provided at least more than one, and when the regeneration tank 230 is provided in two or more, the first sensor 232 and the valve 233 are provided in a plurality of .

When the number of the regeneration tanks 230 is two, the number of the valves 233 located above the regeneration tank 230 corresponds to the number of the regeneration tanks 230. Accordingly, the first transfer control device (not shown) Controls the two or more valves (233) located at the upper part in accordance with the height of the liquid level of the first sensor (232) provided in the regeneration tank (230) to supply the hot melt or polymer solution to the regeneration tank (230), respectively.

Meanwhile, the VOC recycling apparatus 300 is provided in the electrospinning apparatus 1. That is, VOC (Volatile Organic VOC) generated when the hot melt and the polymer solution are sprayed through the nozzle 12 of the nozzle tube 40 provided in each unit 10a, 10b, 10c, 10d of the electrospinning device 1 A distillation unit 320 for distilling and liquefying the condensed VOC through the condensing unit 310 and a condenser 310 for condensing and liquefying the volatile organic compound (VOC) There is provided a VOC recycling apparatus 300 including a solvent storage device 330 for storing a solvent.

Here, the condenser 310 is preferably a water-cooled, evaporative or air-cooled condenser, but is not limited thereto.

The vaporized VOC generated in each of the units 10a, 10b, 10c and 10d is introduced into the condenser 310 and the VOC in the liquefied state generated in the condenser 310 is supplied to the solvent storage device Pipes 311 and 331 are connected to each other. That is, pipes 311 and 331 for interconnecting the units 10a, 10b, 10c and 10d and the condenser 310, the condenser 310 and the solvent storage unit 330 are connected to each other .

In an embodiment of the present invention, the VOC is condensed through the condenser 310, and the condensed and liquefied VOC is supplied to the solvent storage device 330. However, the condenser 310 and the solvent storage It is also possible that a distillation apparatus 320 is provided between the apparatuses 330 so as to separate and sort each solvent when more than one solvent is applied.

VOCs generated in the units 10a and 10c to which the hot melt is injected and VOCs generated in the units 10b and 10d to which the polymer solution is electrospun are supplied to the units 10a, 10b, 10c, and 10d, And a VOC recycling apparatus 330 for recycling are separately provided so as to separately store and recycle the VOC generated at the time of spraying the hot melt and the VOC generated at the time of electrospinning the polymer spinning solution.

Meanwhile, the distillation apparatus 320 is connected to the condenser 310 to vaporize the VOC in the liquefied state by the high-temperature heat and cool it again to supply the liquefied VOC to the solvent storage apparatus 330.

In this case, the VOC recycling apparatus 300 discharges air through the respective units 10a, 10b, 10c, and 10d, and supplies air and cooling water to the vaporized VOC when hot melt or polymer solution is injected, A distillation apparatus 320 for converting the VOC condensed through the apparatus 310 and the condenser 310 into a vaporized state and then cooling the liquid to a liquefied state and a distillation apparatus 320 for passing the liquefied VOC And a solvent storage device 330 for storing the solvent.

Here, the distillation apparatus 320 is preferably a fractionation apparatus, but it is not limited thereto.

The respective units 10a, 10b, 10c and 10d and the condenser 310, the condenser 310 and the distillation unit 320 and the distillation unit 320 and the solvent storage unit 330 are interconnected Pipes 311, 321, and 331 are connected to each other.

On the other hand, the content of the solvent in the polymer spinning solution recovered in the regeneration tank 230 after overflowing is measured, and the content of the solvent is measured by extracting a part of the polymer spinning solution in the recovery tank 230 as a sample, And the analysis and measurement of the polymer solution are carried out by a known method.

When a solvent is required according to the measurement result as described above, the liquid is supplied to the solvent storage device 330, and the VOC in the liquefied state generated during the electrospinning of the hot melt injection or the polymer spinning solution is supplied to the pipe 332 And supplies it to the regeneration tank 230. That is, the liquefied VOC is supplied to the regeneration tank 230 by a required amount according to the measurement result, and is reused and recycled as a solvent.

The case 18 constituting each of the units 10a, 10b, 10c and 10d of the electrospinning apparatus 1 is preferably made of a conductive material, but the case 18 may be made of an insulator, 18 may be used in combination of a conductor and an insulator, or may be made of various other materials.

It is also possible that the insulating member 19 is removed when the upper portion of the case 18 is made of an insulator and the lower portion thereof is used in combination as a conductor. To this end, the case 18 is preferably formed as a case 18 by being coupled with a lower part formed of a conductor and an upper part formed of an insulator, but the present invention is not limited thereto.

As described above, the case 18 is formed of a conductor and an insulator, and the upper part of the case 18 is formed of an insulator so that the collector 18 is separately provided for mounting the collector 13 on the inner surface of the upper part of the case 18 It is possible to eliminate the insulating member 19, which can simplify the structure of the apparatus.

It is also possible to optimize the insulation between the collector 13 and the case 18 so that when 35 kV is applied between the nozzle block 11 and the collector 13 for electrospinning, It is possible to prevent the breakdown of the insulation that may occur between the electrode 18 and other members.

In addition, the leakage current can be stopped within a predetermined range, the current supplied from the voltage generators 14a, 14b, 14c, and 14d can be monitored, the abnormality of the electrospinning apparatus 1 can be detected early, The continuous operation of the electrospinning device 1 for a long time is possible, the production of nanofibers having required performance is stable, and mass production of nanofibers is possible.

Here, the thickness a of the case 18 formed of an insulator is made to satisfy "a = 8 mm".

Therefore, when 40 kV is applied between the nozzle block 11 and the collector 13 to perform electrospinning, an insulation breakdown that may occur between the collector 13 and the case 18 and other members And the leakage current can be limited within a predetermined range.

The distance between the inner surface of the case 18 formed of an insulator and the outer surface of the collector 13 is smaller than the thickness a of the case 18 and the distance between the inner surface of the case 18 and the outer surface of the collector 13 The distance "b" is made to satisfy "a + b = 80 mm".

Therefore, when 40 kV is applied between the nozzle block 11 and the collector 13 to perform electrospinning, an insulation breakdown that may occur between the collector 13 and the case 18 and other members And the leakage current can be limited within a predetermined range.

Meanwhile, the electrospinning device 1 is provided with a thickness measuring device 70. That is, the nanofibers 10a, 10b, 10c and 10d of the electrospinning device 1 are laminated on the substrate 15 at the rear ends of the units 10b and 10d, A thickness measuring device 70 for measuring the thickness of the web and controlling the feed rate V of the base material 15 and the nozzle block 11 according to the measured thickness is provided.

The thickness of the nanofiber web laminated on the substrate 15 after the polymer spinning solution is electrospun in each unit 10b and 10d of the electrospinning device 1 is measured to be thinner than the reference value The discharge speed of the polymeric spinning solution discharged from the nozzle block 11b is increased and the voltage intensity of the voltage generating devices 14b and 14d is increased The thickness of the nanofiber web laminated on the substrate 15 can be increased by increasing the discharge amount of the polymer spinning solution per unit area.

On the other hand, when the thickness of the nanofiber web laminated on the substrate 15 after the polymer spinning solution is electrospun in each unit 10b, 10d of the electrospinning device 1 is measured to be thicker than the reference value, It is possible to accelerate the transfer speed V of the units 10b and 10d or reduce the discharge amount of the polymer spinning solution radiated from the nozzle block 11b and adjust the voltage intensity of the voltage generating devices 14b and 14d, The discharge amount of the spinning solution can be reduced and the thickness of the nanofiber web laminated on the base material 15 can be reduced.

Here, the thickness measuring device 70 is disposed so as to face the upper and lower surfaces of the substrate 15 through the inlet and the outlet, and the distance to the upper or lower portion of the substrate 15 by the ultrasonic measuring method (Not shown) for measuring an ultrasonic longitudinal wave, and a pair of ultrasonic longitudinal wave measuring methods.

The thickness of the nanofiber web laminated on the base material 15 can be calculated through the distance measured by the thickness measuring device 70, which is an ultrasonic measurement method.

That is, the thickness measuring device 70 projects the ultrasonic longitudinal wave and the transverse wave to the substrate 15 on which the nanofiber web is laminated, so that the time when each ultrasonic signal of the longitudinal wave and the transverse wave travels on the substrate 15, The propagation time of longitudinal waves and transverse waves, the propagation time of longitudinal waves and transverse waves at the reference temperature of the substrate 15 on which the nanofiber webs are laminated, The thickness of the nanofibrous web can be calculated by calculating the thickness of the subject from the equation.

By calculating the thickness of the substrate 15 on which the nanofiber web is laminated, the thickness can be precisely measured by self-compensating for the error caused by the variation of the propagation speed with temperature change even when the internal temperature is uniform, It is possible to measure a precise thickness regardless of the type of temperature distribution inside the fiber web.

On the other hand, the electrospinning device 1 is provided with an air permeability measuring device 80. That is, the base 10 is formed by laminating the base 10 on the base 15 through the units 10b and 10d at the rear of the unit 10d located at the rearmost end of each unit 10a, 10b, 10c and 10d of the electrospinning device 1 An air permeability measuring device 80 for measuring the air permeability of the nanofiber web is provided and the air permeability measuring device 80 measures the air permeability of the nanofiber web by ultrasonic waves.

The base material 15 supplied to the air permeability measuring device 80 after the polymer spinning solution is radiated through the units 10b and 10d of the electrospinning device 1 so that the nanofiber webs are laminated is passed through the air permeability measuring device When the air permeability of the nanofiber web is measured largely through the measured values according to the ultrasonic signals projected from the nozzle blocks 80 and 80, the conveyance speed V of each of the units 10b and 10d is decreased or the discharge amount of the nozzle block 11b is increased And the voltage intensity of the voltage generating devices 14b and 14d is adjusted to increase the discharge amount of the polymer spinning solution per unit area so that the amount of the polymer spinning solution is increased on the base material 15 and the air permeability is reduced.

The base material 15 supplied to the aeration degree measuring device 80 after the polymer solution is radiated through the units 10b and 10d of the electrospinning device 1 and the nanofiber webs are laminated, The feed rate V of each unit 10b or 10d may be increased or the discharge amount of the nozzle block 11b may be increased when the air permeability of the nanofiber web is measured through the measurement value according to the ultrasonic signal projected from the nozzle block 80, And the voltage intensity of the voltage generating devices 14b and 14d is adjusted to reduce the discharge amount of the polymer spinning solution per unit area so that the amount of the polymer spinning solution is reduced on the base material 15 to increase the air permeability.

As described above, it is possible to manufacture a nanofiber web having uniform air permeability by controlling the feed rate of each unit 10b, 10d and the nozzle block 11b according to the degree of air permeability after measuring the air permeability of the nanofiber web .

Here, when the air permeability deviation P of the nanofiber web is less than a predetermined value, the feed speed V is not changed from the initial value, and when the deviation amount P is equal to or larger than the predetermined value, Can be changed from the initial value, and it is possible to simplify the control of the conveyance speed (V) by the conveyance speed (V) control device.

It is also possible to control the discharge amount and the voltage of the nozzle block 11b in addition to the control of the feed speed V so that the discharge amount of the nozzle block 11b and the voltage intensity When the deviation amount P is equal to or larger than the predetermined value, the discharge amount and the voltage intensity of the nozzle block 11b are changed from the initial value and the discharge amount of the nozzle block 11b and the voltage intensity are controlled Can be simplified.

In order to control the feeding speed of the base material 15 from which the polymer spinning solution is injected after the hot melt is injected between the hot melt units 10a and 10c of the electrospinning device 1 and the spinning solution units 10b and 10d, A substrate conveyance speed regulating device 30 is further provided.

To this end, the substrate conveying speed regulating device 30 includes a buffering section 31 formed between the hot melt units 10a and 10c of the electrospinning device 1 and the spinning solution units 10b and 10d and the buffering section 31 A pair of supporting rollers 33 and 33 'provided on the supporting rollers 33 and 33' for supporting the base material 15 and an adjusting roller 35 provided between the pair of supporting rollers 33 and 33 ' .

At this time, the support rollers 33 and 33 'are provided in the plurality of nozzles 12 provided in the nozzle tube 40 of the nozzle block 11 in each unit 10a and 10c, And is provided at a line and a rear end of a buffer zone 31 formed between the hot melt units 10a and 10c and the spinning solution units 10b and 10d.

The adjustment roller 35 is disposed between the pair of support rollers 33 and 33 'so that the substrate 15 is wound and moved up and down by the adjustment roller 35, The feeding speed and the moving time of the substrates 15a and 15b between the units 10a and 10c and the spinning solution units 10b and 10d are adjusted.

A sensing sensor (not shown) for sensing the feeding speed of the substrates 15a and 15b is provided between the hot melt units 10a and 10c and the spinning solution units 10b and 10d, And is connected to the main control unit 7 for controlling the movement of the regulating roller 35 in accordance with the feeding speed of the substrates 15a and 15b between the hot melt units 10a and 10c and the spinning solution units 10b and 10d.

In an embodiment of the present invention, the feed speed of the substrates 15a and 15b between the hot melt units 10a and 10c and the spinning liquid units 10b and 10d is sensed and the feed speed of the substrates 15a and 15b sensed The auxiliary belt 16a or the auxiliary belt 16b which is provided outside the collector 13 for transferring the base materials 15a and 15b and which will be described later, (Not shown) that drives the auxiliary belt roller 16b or the motor (not shown) that drives the regulating roller 16a, and the control unit controls the movement of the regulating roller 35 accordingly.

3 to 4, in the nozzle tube 40 of the nozzle block 11 provided in each unit 10a, 10b, 10c, 10d of the electrospinning device 1, An adjustment control device 60 is provided.

That is, the nozzle tube 40 of the nozzle block 11, which is provided in each of the units 10a, 10b, 10c, and 10d and to which the hot melt and the polymer solution are supplied to the plurality of nozzles 12 provided on the upper portion, And a temperature control device 60 for controlling the temperature of the hot melt and the polymer spinning solution.

Here, the flow of the hot melt and the polymer spinning solution in the nozzle block 11 flows from the solution main tank 8 in which the hot melt or the polymer spinning solution is stored through the spinning liquid flow pipe (not shown) And is supplied to the nozzle body 40.

The hot melt and the polymer spinning solution supplied to the nozzle tube 40 of each nozzle block 11 are sprayed and electrospun through a plurality of nozzles 12 to form a nanofiber web on the substrate 15. At this time, a plurality of nozzles 12, which are spaced apart from each other at a predetermined interval in the longitudinal direction (traveling direction) of the substrate, are provided on the nozzle tubes 40 of the respective nozzle blocks 11 and above the respective nozzle tubes 40, And is mounted on the nozzle body 40 in a state of being electrically connected.

The temperature control device 60 controls the temperature control of the hot melt and the polymeric spinning liquid supplied to and discharged from the nozzle tube 40 of each nozzle block 11, A heat ray 41 is provided. 5 to 6, a temperature control device 60 including a heat ray 41 is disposed on the periphery of the nozzle tube 40 of the nozzle block 11 in the nozzle tube 40, The temperature of the hot melt and polymer spinning solution, which is spirally formed on the periphery of the tube 40 and supplied to and introduced into the nozzle tube 40, is adjusted.

The temperature control device 60 is spirally arranged on the periphery of the nozzle tube 40 of the nozzle block 11 in the form of a heat ray 41. However, And the temperature control device 60 may be provided in a plurality of rows in the longitudinal direction of the substrate on the inner peripheral radial direction of the nozzle tube 40 so as to control the temperature of the hot melt and the polymer solution. And may be provided on the inner circumference of the nozzle tube 40 to adjust the temperature of the hot melt and the polymer solution.

In order to control the temperature of the plurality of nozzle tubes 40 provided in each nozzle block 11, each nozzle tube 40 and the temperature regulation controller 60 are connected to the main controller 7, And the temperature of the hot melt and the polymer spinning solution is controlled and controlled by the main control device (7).

7, the substrate 15 to be fed into and fed into each unit 10a, 10b, 10c, and 10d of the electrospinning apparatus 1 is fed, The auxiliary conveying device 16 for controlling the speed is provided with auxiliary belts (not shown) rotating in synchronization with the conveying speed of the substrate 15 so as to facilitate the detachment and conveyance of the substrate 15 in each unit 10a, 10b, 10c, And an auxiliary belt roller 16b for supporting and rotating the auxiliary belt 16a.

The auxiliary belt 16a is rotated by the rotation of the auxiliary belt roller 16b and the substrate 15 is rotated by the rotation of the auxiliary belt 16a by the units 10a, 10b, 10c, 10d. To this end, one of the auxiliary belt rollers 16b is rotatably connected to a motor (not shown).

In the embodiment of the present invention, five auxiliary belt rollers 16b are provided on the auxiliary belt 16a, and one of the auxiliary belt rollers 16b is rotated by the operation of the motor to rotate the auxiliary belt 16a At the same time, the remaining auxiliary belt rollers 16b are rotated. However, the auxiliary belt 16a is provided with two or more auxiliary belt rollers 16b, and one of the auxiliary belt rollers 16b is rotated by the operation of the motor , So that the auxiliary belt 16a and the remaining auxiliary belt roller 16b are rotated.

Meanwhile, in the embodiment of the present invention, the auxiliary transfer device 16 is composed of the auxiliary belt roller 16b and the auxiliary belt 16a that can be driven by the motor. However, as shown in FIG. 8, It is also possible that the roller 16b is made of a roller having a low coefficient of friction so that the roller is rotated by a small force in which the base material 15 is fed and fed.

At this time, it is preferable that the auxiliary belt roller 16b is composed of a roller including a bearing having a low friction coefficient, so that the motor can be removed.

The auxiliary conveying device 16 is composed of the auxiliary belt 16a and the auxiliary belt roller 16b having a low coefficient of friction but only the roller having a low friction coefficient excluding the auxiliary belt 16a So that the substrate 15 can be transported.

In addition, in the embodiment of the present invention, the auxiliary belt roller 16b is applied with a roller having a low coefficient of friction. However, any roller having a low coefficient of friction is not limited in its shape and configuration, It is also possible to apply rollers including bearings such as roller bearings, sliding bearings, sleeve bearings, fluid pressure journal bearings, hydrostatic journal bearings, pneumatic bearings, air bearing bearings, air static bearings and air bearings, It is also possible to apply a roller having a reduced coefficient of friction by including a material and an additive.

Hereinafter, the operation of the electrospinning apparatus according to the present invention will be described with reference to FIGS. 1 to 14. FIG.

First, the substrate 15 is fed through the feed roller 3 provided at the front end of the electrospinning apparatus 1 according to the present invention to the most of the units 10a, 10b, 10c, and 10d of the electrospinning apparatus 1 And is then supplied into and supplied to the unit 10a located at the position shown in Fig.

The base material 15 which is fed into and supplied into the unit 10a of the electrospinning device 1 through the feed roller 3 is connected to the hot melt units 10a and 10c of the units 10a, 10b, 10c and 10d, And the polymer spinning solution is electrospun as it passes through spinning solution units 10b and 10d located at the rear ends of the hot melt units 10a and 10c.

At this time, the base material 15 which is fed into and supplied to the respective units 10a, 10b, 10c and 10d of the electrospinning device 1 through the feeding roller 3 is positioned on the collector 13, 14b, 14c and 14d is generated on the collector 13 through the nozzle 12 and the base material 15 on the collector 13 on which the high voltage is generated is filled with the hot melt And the polymer spinning solution are sequentially electrospun through the nozzle 12 of the nozzle block 11.

Here, the hot melt and the polymer spinning solution filled in each of the solution main tanks 8 are supplied to the nozzle block 11a having a nozzle tube 40 to which a high voltage is applied through a metering pump (not shown) The nozzle 12 and the nozzle 12 having the nozzle tube body 40 in which the polymeric spinning solution is electrospun is supplied continuously and the hot melt and the polymer spinning solution supplied to the respective nozzles 12 Are stacked on the base material 15 while being focused and electrospun on the collector 13 with a high voltage applied thereto through the nozzle 12.

9 to 10, each nozzle of the nozzle tube body 40 installed only at both ends of the nozzle block 11a provided in the hot melt unit 10a, 10c of the electrospinning apparatus 1, The base material 15 in which the hot melt is sprayed through the hot melt unit 10 and the hot melt unit 10a and 10c and the hot melt is sprayed to both ends in the width direction is discharged into the spinning solution units 10b and 10d The polymer spinning solution is electrospun through the nozzles 12 of the plurality of nozzle tubes 40 arranged in the nozzle block 11b to be installed.

That is, the hot melt is sprayed from the nozzles 12 of the nozzle tube body 40 arranged at both ends of the nozzle block 11a of the hot melt unit 10a positioned at the tip of each of the units 10a, 10b, 10c, The substrate 15 to be transferred while being sprayed onto both end portions in the width direction of the hot melt is taken in and supplied to the spinning solution unit 10b positioned at the rear end of the hot melt unit 10a and the spinning solution unit 10b, The polymer spinning solution is injected through the nozzles 12 of the nozzle tube 40 arranged in a plurality of nozzle blocks 11b on the substrate 15 supplied with the polymer spinning solution, The substrate 15 to be transferred is made of a nanofiber or a nanofiber filter while spraying the hot melt and the polymer spinning solution while passing through the hot melt unit 10c for spraying the hot melt and the spinning solution unit 10d for electrospinning the polymer spinning solution do.

Each of the solution main tanks 8 connected to the respective units 10a, 10b, 10c and 10d is filled with hot melt or polymer solution, and the hot melt units 10a and 10c are filled with hot melt 8, and the solution tank 8 is filled with the spinning liquid solution 10b, 10d located at the rear end thereof.

On the other hand, a nozzle tube body 40 is provided at both ends and a central portion of the nozzle block 11a in the hot melt units 10a and 10c, It is also possible to spray the hot melt at both end portions in the width direction and at the center portion.

As described above, since the nozzle tube body 40 is arranged at both end portions and the central portion of the nozzle block 11a, the adhesion of the nanofiber web laminated to the substrate 15 and the substrate 15 can be improved , The position and the number of the nozzles 12 are not limited thereto.

In this way, the base material 15 which is introduced into and supplied to the unit 10a located at the foremost end among the units 10a, 10b, 10c and 10d of the electrospinning device 1 is driven by a motor (not shown) The auxiliary belt 16b of the auxiliary feeding device 16 and the auxiliary belt 16a driven by the rotation of the auxiliary belt roller 16b are fed to the unit 10b located at the rear end thereof, 10b, 10c, and 10d by the operation of the auxiliary transfer device 16 provided in each of the units 10a, 10b, 10c, and 10d, the substrate 15 is transferred into each of the units 10a, The hot melt and the polymeric spinning solution of the same kind are respectively electrospinned on the base material 15 flowing in and supplied into the molds 10a, 10b, 10c and 10d, or the hot melt and the polymeric spinning solution of different kinds are respectively electrospun, The nanofiber web is laminated on the substrate 15 to form a nanofiber or nanofiber filter .

The hot melt and polymer spinning solution overflowed from the nozzle block 11 by the overflow device 200 provided in the electrospinning device 1 is supplied to the solution recovery path 250 ), And the recovered hot melt and polymer solution is reused and recycled again.

The VOC recycling apparatus 300 included in the electrospinning apparatus 1 may be used to control the amount of VOCs generated during the injection of the hot melt and the polymer spinning solution through the nozzles 12 in the respective units 10a, 10b, 10c, Reuse and reuse.

That is, hot melts are sprayed onto the substrate 15 through the nozzles 12 in the respective units 10a, 10b, 10c, and 10d, or vaporization generated when the polymer spinning solution is electrospun on the substrate 15 VOC in the vapor state is discharged to the condenser 310 through the pipes 311 and 331 and the vaporized VOC discharged into the condenser 310 is condensed and changed into a liquefied state and then discharged to the solvent storage device 330 Respectively, and the VOC stored in the solvent storage device 330 is recycled and reused.

As described above, the vaporized VOC generated in each unit 10a, 10b, 10c, and 10d of the electrospinning device 1 and discharged to the condenser 310 is cooled and condensed in the condenser 310, Cooled by a cooling method such as air cooling or evaporation, and is condensed to change into a liquefied state. Thereafter, the condensed liquefied VOC is condensed through the condenser 310, and then the liquefied VOC is distilled to the distillation apparatus 320 And the distillation unit 320 is moved to the distillation unit 320. The VOCs in the liquefied state are sequentially vaporized in accordance with the difference in boiling point by the heat at a high temperature, and the vaporized VOCs are separated and classified by the solvent and liquefied and discharged.

At this time, the liquefied VOC which is distilled through the distillation unit 320 is vaporized in the order of the solvent having a low boiling point and the solvent having a high boiling point. That is, the VOC in the liquefied state is evaporated in the order of lower boiling point, and the vaporized and liquefied VOC is discharged to the piping 311, 321, and 331 provided in the lower direction from the piping provided in the upper direction of the distillation apparatus 320 And is supplied to each solvent storage device 330.

In this way, the VOCs composed of various kinds of mixed solvents are classified according to the respective solvents at the time of discharge and classified into the respective solvent storage units 330, and classified into the respective solvents, classified into the solvents stored in the solvent storage unit 330 Is again added to the hot melt and polymer solution for solvent reuse and recycling.

After the hot melt is injected through the hot melt units 10a and 10c located at the ends of the electrospinning device 1, the polymer spinning solution is electrospun through the spinning solution units 10b and 10d located at the rear end, The substrate 15 on which the fibrous web is laminated is passed through the thickness measuring device 70 located at the rear end of the units 10b and 10d and passes through the thickness measuring device 70, The ultrasonic longitudinal wave and the transverse wave are projected together to measure the time during which the ultrasonic signals of the longitudinal wave and the transverse wave move back and forth on the base 15, that is, the propagation time of the longitudinal wave and the transverse wave.

Then, from the predetermined calculation formula using the measured propagation time of the longitudinal wave and the transverse wave, the propagation speed of the longitudinal wave and the transverse wave at the reference temperature of the substrate 15 on which the nanofiber web is laminated, and the temperature constants of the longitudinal wave and transverse wave propagation velocity, The thickness of the nanofiber web laminated on the substrate 15 is measured by calculating the thickness of the nanofiber web.

When the thickness of the nanofiber web laminated on the substrate 15 passing through the units 10b and 10d through the thickness measuring device 70 is measured to be thinner than the reference value The discharge speed per unit area of the polymer spinning solution radiated from the nozzle block 11b by decreasing the conveyance speed V of the subsequent units 10b and 10d or adjusting the voltage intensity of the voltage generating devices 14b and 14d The thickness of the nanofiber web is increased.

When the thickness of the nanofiber web laminated on the substrate 15 passing through the units 10b and 10d through the thickness measuring device 70 is measured to be thicker than the reference value The discharge amount per unit area of the polymer solution used in the nozzle block 11b is increased by increasing the transfer speed V of the next unit 10b or 10d or adjusting the voltage intensity of the voltage generator 14b or 14d So that the thickness of the nanofiber web is made thin.

Here, when the conveying speed of the substrate 15 passing through the thickness measuring device 70 is fast or slow, the substrate conveying speed regulating device 30 is moved to the substrate 15 conveyed through the auxiliary conveying device 16, To adjust the speed of the motor.

That is, the detection sensors provided in the electrospinning device 1 are arranged in the hot melt units 10a and 10c positioned at the ends of the units 10a, 10b, 10c and 10d, and the spinning liquid units 10b, 10b, 10c and 10d is faster than the conveying speed in the spinning liquid units 10b, 10d, the conveying speed of the substrate 15a between the hot-melt units 10a, Likewise, in order to prevent sagging of the substrate 15a conveyed in the hot melt units 10a and 10c, an adjusting roller (not shown) provided between the pair of supporting rollers 33 and 33 ' The hot melt units 10a and 10c are transported to the outside of the hot melt units 10a and 10c among the base materials 15 transferred to the spinning liquid units 10b and 10d in the hot melt units 10a and 10c while moving downward, And the buffer 15a, which is excessively transferred to the buffer zone 31 located between the spinning solution units 10b and 10d, The substrate 15a is prevented from sagging and wrinkling while being controlled so that the feeding speed of the base material 15a in the hot melt units 10a and 10c and the feeding speed of the base material 15b in the spinning liquid units 10b and 10d become equal to each other, do.

On the other hand, when the detection sensor detects that the spinning solution units 10b and 10d in which the conveying speed of the base material 15a in the hot melt units 10a and 10c located at the front ends of the units 10a, 10b, 13 to 14, in order to prevent the base material 15b fed in the spinning liquid units 10b, 10d from tearing, The spinning solution units 10b and 10d in the hot melt units 10a and 10c are disposed between the pair of support rollers 33 and 33 'while moving the adjustment roller 35 on which the base material 15 is wound, 10b and 10d are transferred to the outside of the hot melt units 10a and 10c in the substrate 15 to be transferred to the hot melt units 10a and 10c and the spinning solution units 10b and 10d, ) To the spinning solution units 10b and 10d so that the substrate 15a in the hot melt units 10a and 10c 15a and the transfer speed of the base material 15b in the spinning liquid units 10b, 10d become equal to each other, while preventing the substrate 15b from being cut off.

By controlling the transfer speed of the substrate 15b to be transferred into the spinning liquid units 10b and 10d of the units 10a, 10b, 10c and 10d by the above-described structure, the respective units 10a, 10b and 10c The effect of making the feeding speed of the base material 15b in the spinning liquid units 10b and 10d in the hot melt units 10a and 10d equal to the feeding speed of the base material 15a in the hot melt units 10a and 10c can be obtained.

As described above, the base material 15 (15a, 15b, 15c, 15d) is formed by electrospinning the hot melt and the polymer spinning solution while passing through the units 10a, 10b, 10c and 10d of the electrospinning device 1, ) Is subjected to a back-end process of laminating through a laminating apparatus (90), and is manufactured as a final product.

The air permeability of the substrate 15 laminated through the laminating apparatus 90 is measured by the air permeability measuring apparatus 80 and the air permeability of the units 15a to 15d provided at the tip ends of the units 10a, 10b, 10c and 10d 10a and 10c, and the air permeability of the nanofiber web in which the polymer spinning solution is electrospun and laminated on the base material 15 is measured through the units 10b and 10d provided at the rear end thereof, The feed rate V of the base material 15 and the nozzle block 11 are controlled according to the value to adjust the air permeability of the nanofiber web.

That is, when the air permeability of the nanofiber web laminated on the base material 15 is measured largely through the units 10b and 10d of the electrospinning device 1, the feeding speed of the units 10b and 10d V is increased or the voltage intensity of the voltage generating devices 14b and 14d is adjusted to increase the discharge amount per unit area of the nozzle block 11 to increase the amount of the polymer solution to be laminated on the substrate 15, And when the air permeability of the nanofiber web laminated on the base material 15 is measured through each of the units 10b and 10d, the feeding speed V of the units 10b and 10d is increased, The voltage intensity of the voltage generators 14b and 14d is adjusted to reduce the discharge amount per unit area of the nozzle block 11 to reduce the amount of the polymer solution to be laminated on the substrate 15, thereby increasing the air permeability.

After the air permeability of the nanofiber web laminated on the base material 15 is measured, the conveying speed of each of the units 10b and 10d and the nozzle block 11 are controlled according to the measured air permeability, A nanofiber web can be produced.

In the present invention, the electrospinning device 1 is a top-down electrospinning device, four units 10a, 10b, 10c and 10d are sequentially provided, and the thickness measuring device 70 and the substrate conveyance speed regulating device The laminating apparatus 90 and the air permeability measuring apparatus 80 are provided at the rear ends of the respective units 10a, 10b, 10c and 10d. However, when the electrospinning apparatus 1 is provided with the bottom- The number of the units 10a, 10b, 10c, and 10d may be four or more, and the number of the units 10a, 10b, 10c, and 10d may be four or more, It is preferable that an apparatus suitable for a desired one of the substrate conveyance speed regulating device 30, the flip device 110, the laminating device 90 and the air permeability measuring device 80 is provided.

In addition, although the overflow device 200 and the VOC recycling device 300 are provided in the electrospinning device 1 at the same time in the embodiment of the present invention, the overflow device 200 and the VOC recycling device 300, May be separately provided.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. Anyone with it will know easily.

1: electrospinning device, 3: feed roller,
5: take-up roller, 7: main control device,
8: solution main tank, 10a, 10c: hot melt unit,
10b, 10d: spinning liquid unit, 11, 11a, 11b: nozzle block,
12: nozzle, 13: collector,
14, 14a, 14b, 14c and 14d: voltage generating device,
15, 15a, 15b: substrate, 16: auxiliary transfer device,
16a: auxiliary belt, 16b: auxiliary belt roller,
18: case, 19: insulating member,
30: substrate conveyance speed regulating device, 31: buffer section,
33, 33 ': support roller, 35: regulating roller,
40: nozzle tube, 41: hot wire,
60: Temperature control device, 70: Thickness measuring device,
80: air permeability measuring apparatus, 90: laminating apparatus,
200: overflow device, 211, 231: stirring device,
212, 213, 214, 233: valve, 216: second transfer pipe,
218: second conveyance control device, 220: intermediate tank,
222: second sensor, 230: regeneration tank,
232: first sensor, 240: supply pipe,
242: supply control valve, 250: solution recovery path,
251: first transfer pipe, 300: VOC recycling apparatus,
310: condenser, 311, 321, 331, 332: piping,
320: distillation device, 330: solvent storage device.

Claims (10)

An electrospinning device for producing nanofibers,
A nozzle for spraying hotmelt onto a substrate supplied from the outside, the nozzle having a pin-shaped nozzle arranged in the longitudinal direction of the substrate (for example, A hot melt unit having a nozzle block in which a plurality of nozzle tubes are arranged at both ends of the nozzle block;
At least one solution main tank filled with a spinning solution and a polymer spinning solution filled in the solution main tank are provided inside the case for electrospinning the spinning solution for injecting the polymer spinning solution onto an external substrate, A spinning solution unit having a nozzle block having a plurality of nozzle tubes arranged in the width direction of the nozzle block, the nozzle tubes having a plurality of nozzles arranged in the longitudinal direction of the substrate (moving direction);
A collector disposed in each of the units, the collector being spaced apart from the nozzle by a predetermined distance in order to collect the hot melt and the polymer solution for spraying from nozzles provided in the nozzle block;
A voltage generator for generating a voltage in the collector; And
An auxiliary transfer device for transferring the substrate;
A condenser for condensing and liquefying the VOC generated in each unit;
A distillation device for distilling and liquefying the condensed VOC through the condensing device;
A storage device for storing the liquefied solvent in the distillation apparatus; A VOC recycling apparatus for reusing and recycling a solvent in a storage tank into which a VOC distilled and liquefied in the distillation apparatus is classified and stored as a polymer spinning solution;
And,
Wherein at least one of the hot melt unit and the spinning solution unit is provided in a plurality of alternatingly arranged fashion.
The method according to claim 1,
A recovery tank for storing the hot melt and the polymer spinning solution recovered in connection with the spinning solution recovery path, a recovery tank for storing the hot melt and the polymer spinning solution recovered in the nozzle block of each unit, An overflow device including an intermediate tank in which a hot melt and a polymer solution are connected to a tank and a solution main tank through a transfer pipe, and the hot melt and the polymer solution are supplied to the nozzle block through a supply pipe in the intermediate tank;
And an electrospinning device for manufacturing nanofibers.
delete The method according to claim 1,
Wherein the upper part of the case is made of an insulator and the lower part is made of a conductor, and the upper and lower parts of the case are mutually coupled to each other.
The method according to claim 1,
The thickness of the nanofiber web is measured on the base material conveyed by the ultrasonic wave and is set at the rear end of the spinning solution unit. The thickness of the nanofiber web is measured according to the measured thickness of the nanofiber web, To adjust the thickness of the nanofiber web;
And an electrospinning device for manufacturing nanofibers.
The method according to claim 1,
Measuring the air permeability of the nanofiber web sprayed on the substrate by ultrasonic waves and controlling the feeding speed of the substrate and the voltage intensity of the voltage generator according to the measured air permeability of the nanofiber web, An air permeability measuring device for controlling the air permeability of the nanofiber web;
And an electrospinning device for manufacturing nanofibers.
The method according to claim 1,
A buffer zone formed between the hot melt unit and the spinning solution unit; a pair of support rollers for supporting the substrate on the buffer zone; and a pair of support rollers provided between the pair of support rollers, A substrate conveying speed regulating device including at least one regulating roller for regulating a conveying speed of the substrate by vertical movement of the regulating rollers;
And an electrospinning device for manufacturing nanofibers.
The method according to claim 1,
A temperature control device which is spirally formed on the periphery of each of the nozzle blocks of the nozzle block and is formed in a hot line shape to control the temperature of the hot melt and the polymer solution to be supplied into the nozzle tube;
And an electrospinning device for manufacturing nanofibers.
The method according to claim 1,
Wherein the hot melt is sprayed to both end portions of the nozzle block of the hot melt unit only in the widthwise direction of the substrate to be transferred.
The method according to claim 1,
Wherein the hot melt is sprayed from a nozzle provided in a nozzle tube of the hot melt unit and supplied to a spinning solution unit located at a rear end of the substrate on which the hot melt is sprayed, Wherein the step of laminating and forming the nanofiber web is alternately repeated.

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