A method of manufacturing a display device includes: preparing a cover window including a bent part on a side surface thereof, and a guide film including a surface on which a display panel and an adhesive layer are arranged; arranging the cover window and the guide film in a face-to-face manner such that the adhesive layer faces the cover window; seating the guide film onto a seating pad of a first jig; pre-forming the display panel by bringing opposite ends of the guide film into close contact with opposite side surfaces of the seating pad using a pair of push members; and joining the display panel with the cover window by bringing the adhesive layer into contact with the cover window.
B32B 7/12 - Interconnection of layers using interposed adhesives or interposed materials with bonding properties
B29C 53/04 - Bending or folding of plates or sheets
B29C 65/00 - Joining of preformed partsApparatus therefor
B29C 65/48 - Joining of preformed partsApparatus therefor using adhesives
B32B 37/10 - Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by the pressing technique, e.g. using direct action of vacuum or fluid pressure
B32B 38/00 - Ancillary operations in connection with laminating processes
The present disclosure relates to a secondary battery manufacturing system having a multi-packaging unit, in which multiple packaging units of a secondary battery manufacturing facility are provided and a transfer box on which an electrode assembly is accommodated is transferred to each packaging unit by a transfer unit, wherein the secondary battery manufacturing system includes: an electrode supply unit equipped with a plurality of stacking devices for supplying an electrode assembly in which a plurality of battery cells are stacked; a tab-welding unit; at least one packaging unit; at least one temporary buffer; and a transfer unit.
The present disclosure relates to a secondary battery manufacturing system in which a packaging unit of a secondary battery manufacturing facility are configured to have multiple packaging units, and having a multipackaging unit such that a transfer box in which an electrode assembly is seated is transferred to each of the packaging units by a transfer unit, and including an electrode supply unit having a plurality of stacking devices supplying an electrode assembly in which a plurality of battery cells are stacked, a tab welding unit, at least one packaging unit, at least one temporary buffer, and a transfer unit.
A method of manufacturing a display device includes: preparing a cover window including a bent part on a side surface thereof, and a guide film including a surface on which a display panel and an adhesive layer are arranged; arranging the cover window and the guide film in a face-to-face manner such that the adhesive layer faces the cover window; seating the guide film onto a seating pad of a first jig; pre-forming the display panel by bringing opposite ends of the guide film into close contact with opposite side surfaces of the seating pad using a pair of push members; and joining the display panel with the cover window by bringing the adhesive layer into contact with the cover window.
B32B 7/12 - Interconnection of layers using interposed adhesives or interposed materials with bonding properties
B29C 53/04 - Bending or folding of plates or sheets
B29C 65/00 - Joining of preformed partsApparatus therefor
B29C 65/48 - Joining of preformed partsApparatus therefor using adhesives
B32B 37/10 - Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by the pressing technique, e.g. using direct action of vacuum or fluid pressure
B32B 38/00 - Ancillary operations in connection with laminating processes
A method of manufacturing a display device includes: preparing a cover window including a bent part on a side surface thereof, and a guide film including a surface on which a display panel and an adhesive layer are arranged; arranging the cover window and the guide film in a face-to-face manner such that the adhesive layer faces the cover window; seating the guide film onto a seating pad of a first jig; pre-forming the display panel by bringing opposite ends of the guide film into close contact with opposite side surfaces of the seating pad using a pair of push members; and joining the display panel with the cover window by bringing the adhesive layer into contact with the cover window.
B32B 7/12 - Interconnection of layers using interposed adhesives or interposed materials with bonding properties
B32B 37/10 - Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by the pressing technique, e.g. using direct action of vacuum or fluid pressure
B32B 38/00 - Ancillary operations in connection with laminating processes
B29C 53/04 - Bending or folding of plates or sheets
B29C 65/48 - Joining of preformed partsApparatus therefor using adhesives
B29C 65/00 - Joining of preformed partsApparatus therefor
A method of manufacturing a display device includes: preparing a cover window including a bent part on a side surface thereof, and a guide film including a surface on which a display panel and an adhesive layer are arranged; arranging the cover window and the guide film in a face-to-face manner such that the adhesive layer faces the cover window; seating the guide film onto a seating pad of a first jig; pre-forming the display panel by bringing opposite ends of the guide film into close contact with opposite side surfaces of the seating pad using a pair of push members; and joining the display panel with the cover window by bringing the adhesive layer into contact with the cover window.
B32B 7/12 - Interconnection of layers using interposed adhesives or interposed materials with bonding properties
B32B 37/10 - Methods or apparatus for laminating, e.g. by curing or by ultrasonic bonding characterised by the pressing technique, e.g. using direct action of vacuum or fluid pressure
B32B 38/00 - Ancillary operations in connection with laminating processes
B29C 53/04 - Bending or folding of plates or sheets
B29C 65/48 - Joining of preformed partsApparatus therefor using adhesives
B29C 65/00 - Joining of preformed partsApparatus therefor
A substrate peeling apparatus includes a support member and absorption pads. The support member, having a quadrangular shape, includes first and second vertexes diagonally facing each other in a first direction, and third and fourth vertexes diagonally facing each other in a second direction crossing the first direction. The absorption pads is disposed on the support member. The absorption pads are arranged in rows in a direction parallel to the first direction and at least one absorption pad of each row is arranged in a direction parallel to the second direction. An absorption pad of each row includes a hole having an increasing internal diameter as a distance in the first direction between the each row and the first vertex increases. An internal diameter of an absorption pad in a row positioned halfway between the first and second vertexes has a maximum internal diameter.
A manufacturing device for a liquid crystal display panel includes a stage including a first stage part and second stage part. The stage is configured to support a substrate laminate. A knife includes an entrance portion and a rigidity securing portion. The knife is configured to peel a support substrate of the substrate laminate. The stage is configured to rotate in a direction parallel with a surface of the stage. The rigidity securing portion of the knife is thicker than an entrance portion of the knife.
G02F 1/13 - Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulatingNon-linear optics for the control of the intensity, phase, polarisation or colour based on liquid crystals, e.g. single liquid crystal display cells
B32B 38/00 - Ancillary operations in connection with laminating processes
B32B 38/10 - Removing layers, or parts of layers, mechanically or chemically
9.
POROUS WATERPROOF COMPONENT, POROUS WATERPROOF FILM, AND VEHICLE ELECTRONICS
The present invention relates to a porous waterproof component, a porous waterproof film, and vehicle electronic unit, and the porous waterproof component (1) mountable on a housing body (110) having a porous opening part comprises: a cylindrical porous path forming member (20) for forming a porous path (R) between an internal space (110a) and an external space (110b) of the housing body (100); and a porous waterproof film (10A) provided in the porous path forming member (20) so as to close the porous path, the porous waterproof film (10A) having a nano-fiber layer made from a water repellent nano-fiber. The porous waterproof film (10A) is preferably made from only the water repellent nano-fiber or is made from the water repellent nano-fiber and a reinforcing material layer laminated on the water repellent nano-fiber, and can properly adjust the internal pressure of the vehicle electronic unit through high air-permeability as well as water repellency.
B60R 16/00 - Electric or fluid circuits specially adapted for vehicles and not otherwise provided forArrangement of elements of electric or fluid circuits specially adapted for vehicles and not otherwise provided for
B60R 16/02 - Electric or fluid circuits specially adapted for vehicles and not otherwise provided forArrangement of elements of electric or fluid circuits specially adapted for vehicles and not otherwise provided for electric
B60Q 1/00 - Arrangement of optical signalling or lighting devices, the mounting or supporting thereof or circuits therefor
B60Q 1/04 - Arrangement of optical signalling or lighting devices, the mounting or supporting thereof or circuits therefor the devices being primarily intended to illuminate the way ahead or to illuminate other areas of way or environments the devices being headlights
10.
AIR-PERMEABLE WATER RESISTANT FILM FOR ELECTRONIC DEVICE AND ELECTRONIC DEVICE THEREFOR
The present invention relates to an air-permeable water resistant film for an electronic device and the electronic device therefor, wherein: the air-permeable water resistant film (10A) for an electronic device can be provided in an air-permeable portion that requires water resistant and ventilation properties in an electronic housing body; the air-permeable water resistant film (10A) comprises nanofiber layers (11) having water repellent nanofiber; and the water resistant film (10A) can be formed by only the water repellent nanofiber layers (11) or can be formed by a structure in which stiffening layers are stacked in the water repellent nanofiber layers (11). Furthermore, the present invention provides the air-permeable water resistant film for an electronic device, which has high ventilation properties and water resistant properties.
The present invention provides a separator and a method for manufacturing the separator. The separator includes a first nanofiber layer (20) which has a lattice shape when viewed from a plan view, a second nanofiber layer (30) which is provided on a first surface of the first nanofiber layer (20) and is thinner than the first nanofiber layer, and a third nanofiber layer (40) which is provided on a second surface of the first nanofiber layer and is thinner than the first nanofiber layer. The thickness of the first nanofiber layer ranges from 7 μm to 30 μm. The thickness of each of the second and third nanofiber layers ranges from 1 μm to 5 μm. The present invention can provide a separator which has high insulation, high dendrite resistance, high ion conductivity and high mechanical strength.
The present invention relates to a separator, a method for preparing a separator, and an apparatus for preparing a separator. The separator (101) comprises a polyethylene terephthalate fiber layer (110), and nanofiber layers (120, 130), wherein the polyethylene terephthalate fiber layer (110) is prepared by forming a sheet through a paper-making method for preparing paper by using a polyethylene terephthalate fiber, and pressing the sheet in the heated state, thereby allowing the separator to have high mechanical strength, high insulation, high dendrite resistance, high wettability, and high ion conductivity.
The present invention relates to an apparatus for holding a lengthwise panel of a cardboard sheet. The present invention allows insertion of a lengthwise support body into a holder while firmly supported, and additionally, by allowing the pressure applied to be adjusted on the basis of the thickness of the cardboard sheet, has the benefit of preventing damage to the lengthwise support body or preventing same from becoming unseated from the holder when pressure is being applied to the lengthwise support body.
B31B 3/60 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for uniting opposed surfaces or edges, or for taping
B31B 3/74 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for effecting auxiliary operations
B31B 3/02 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for feeding or positioning sheets, blanks, or webs
B31B 3/46 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs by plungers moving through folding dies and interconnecting side walls during such movement
The present invention relates to an apparatus for automatically inserting a tab of a cardboard sheet into a groove to make a double-walled cardboard box using a cardboard sheet. The present invention allows folding a double-walled cardboard box in which the inner wall and the outer wall are separated from each other by a connecting piece, thereby speeding up the operation and maintaining a uniform degree of completeness in products. Additionally, the present invention has the benefits of significantly reducing operational expenses and facilitating automatic insertion of the tab into the groove.
B31B 3/60 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for uniting opposed surfaces or edges, or for taping
B31B 3/46 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs by plungers moving through folding dies and interconnecting side walls during such movement
B31B 3/26 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs
B31B 3/74 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for effecting auxiliary operations
15.
APPARATUS FOR FORMING WIDTHWISE PANELS OF CARDBOARD SHEET
The present invention relates to an apparatus for forming widthwise panels on a cardboard sheet, the apparatus comprising: a pair of widthwise panel folding parts for adjusting the height and width of widthwise inner walls so as to match the height and width of widthwise panels, which are folded at right angles with respect to the central panel, and for folding widthwise inner walls by rotating to the central panel side, so as to overlap with a widthwise outer walls; tab insertion parts, which are coupled to the widthwise panel folding parts, by being linked on one side thereof, and which slide in the direction of a shaft so that tabs formed on both ends of the folded widthwise inner wall are inserted into settling grooves of the folded lengthwise panel; a pair of width adjusting means, which are connected to the pair of widthwise panel folding parts, and which, to adjust the width thereof, move same in the width direction on the basis of the width of the cardboard sheet; and a driving part, which is connected to the widthwise panel folding parts via the shaft, for rotating the widthwise panel folding parts.
B31B 3/26 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs
B31B 3/46 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs by plungers moving through folding dies and interconnecting side walls during such movement
B31B 3/74 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for effecting auxiliary operations
16.
APPARATUS FOR ADJUSTING HEIGHT FOR FORMING WIDTHWISE PANEL OF CARDBOARD SHEET
The present invention relates to an apparatus for forming widthwise panels of a cardboard sheet, the apparatus comprising: a pair of widthwise panel folding parts for adjusting the height and width of widthwise inner walls so as to match the height and width of widthwise panels, which are folded at right angles with respect to the central panel, and for folding the widthwise inner walls by rotating to the central panel side, so as to overlap with widthwise outer walls; a pair of width adjusting means, which are connected to the widthwise panel folding parts, and move the widthwise panel folding parts in the width direction for adjusting the widths of the widthwise panel folding parts on the basis of the width of the cardboard sheet; and a driving part, which is connected to the widthwise panel folding parts by means of a shaft, and which rotates the widthwise panel folding parts, wherein widthwise panel folding parts comprises: a rotating block, which is connected to the shaft, and which slides in the shaft direction and rotates; a pressurizing means coupled on one side of the rotating block so as to control the length in the height direction; and a fixing means, which penetrates the pressurizing means and is coupled to the rotating block, and which elastically supports the pressurizing means.
B31B 3/26 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs
B31B 3/46 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for folding sheets, blanks, or webs by plungers moving through folding dies and interconnecting side walls during such movement
B31B 3/74 - Machinery characterised by making boxes or cartons by folding single-piece sheets, blanks, or webs and having means for effecting auxiliary operations
The present invention relates to a separator, a method for manufacturing a separator, and an apparatus for manufacturing a separator, the separator (100) comprising: one cellulose fiber layer (110); a nanofiber layer (120) which is coupled to one surface of the cellulose fiber layer (110); and another nanfiber layer which is coupled to the other surface of the cellulose fiber layer (110), wherein the cellulose fiber layer (110) has a width of 1μm-40μm, is made from a cellulose fiber having an average diameter of 0.1μm-10μm, and wherein the cellulose fiber layer (110) is made from the cellulose fiber having an average length of at least 2.0mm, thereby providing the separator having high conductivity strength, high conductivity, high durability to dendrite, and high ion conductivity.
The present invention relates to an apparatus for manufacturing a separator, and more particularly, to an apparatus for manufacturing a separator comprising a structure in which a first fiber layer further comprising a first fiber, and a second fiber layer further comprising a second fiber having a smaller average diameter than that of the first fiber are stacked, the apparatus for manufacturing the separator comprising: a long sheet conveying device (10) provided with a conveying tool (19) for conveying a long sheet, and a long sheet inversion tool (15); a melt-blown spinning device (20) for forming the first fiber layer on one surface of the long sheet (110); an electro-spinning device (40) for forming a second spun layer on one surface of the long sheet (110), wherein the melt-blown spinning device (20), the long sheet inversion tool (15), and the electro-spinning device (40) are arranged, in order, along a long sheet conveying direction, and wherein a high-quality separator having desired qualities can be mass-produced at high productivity, without producing a droplet impact.
The present invention relates to an apparatus for manufacturing a separator, and more particularly, to an apparatus for manufacturing a separator comprising a structure in which a first fiber layer further comprising a first fiber that is manufactured from a predetermined polymer material, and a second fiber that is manufactured from a material identical to the predetermined polymer material are stacked, and provides the apparatus for manufacturing the separator comprising: a long sheet conveying device (10) further comprising a conveying tool (19) and a long sheet inversion tool (15); a melt-blown spinning device (20)for forming the first fiber layer on one surface of a long sheet (110); an electro-spinning device (40) for forming the second fiber layer on one surface of the long sheet (110) by using an upward direction nozzle, wherein the melt-blown spinning device (20), the long sheet inversion tool (15), and the electro-spinning device (40) are arranged, in order, along a long sheet conveying direction, and wherein a high-quality separator having desired qualities can be mass-produced at high productivity, without producing a droplet impact.
The present invention relates to a separator and a method for manufacturing a separator, and provides a separator comprising: a first nanofiber layer (20) having a lattice shape from a level view; a second nanofiber layer (30) which is installed on one surface of the first nanofiber layer (20) and is thinner than the first nanofiber layer (20); the separator (10) provided with a third nanofiber layer (40), which is installed on the other surface of the first nanofiber layer (20) and is thinner than the first nanofiber layer (20), wherein the first nanofiber layer (20) has a width between 7μm-30μm, the second nano fiber layer (30) and the third nanofiber layer (40) both have a width between 1μm-5μm, thereby providing the separator having high conductivity, high durability to dendrite, high ion conductivity, and high mechanical strength.
The present invention relates to an electrospinning apparatus and to an apparatus for manufacturing nanofibers. The electrospinning apparatus comprises: a nozzle block (250) in which a plurality of nozzles (240) are two-dimensionally arranged; and a device (400) for supplying polymer solutions. The electrospinning apparatus discharges the polymer solutions onto an elongate sheet so as to deposit the nanofibers. The device (400) for supplying the polymer solutions includes: polymer-solution tanks (411, 412) for storing a plurality of types of polymer solutions that comprise different components therein; and polymer-solution flow pipes (421 to 427) for enabling the plurality of types of polymer solutions to flow therethrough. The nozzle block (250) has tubular bodies (271 to 277), one end of each of which is closed and the other end of each of which serves as a port for supplying the polymer solutions. Each tubular body has a predetermined number of nozzles (240) arranged in the lengthwise direction of each tubular body. Polymer-solution flow pipes (431 to 437) for enabling the polymer solutions to flow therethrough are connected to the respective ports for supplying the polymer solutions of the tubular bodies. Thus, nozzles can be easily managed, and various methods for supplying polymer solutions can be set.
D01D 13/00 - Complete machines for producing man-made threads
D04H 1/728 - Non-woven fabrics formed wholly or mainly of staple fibres or like relatively short fibres characterised by the method of forming fleeces or layers, e.g. reorientation of fibres the fibres being randomly arranged by electro-spinning
D01D 5/00 - Formation of filaments, threads, or the like
22.
FIELD EMISSION DEVICE AND NANOFIBER MANUFACTURING DEVICE
Provided is a field emission device capable of mass-producing with high productivity nanofibers having uniform quality, even in the case of field-emission by permitting high voltage to a collector while grounding a nozzle block. The field emission device (20) is equipped with a collector (150), a nozzle block (110), and a power device (160) having a positive electrode that connects to the collector (150), and a negative electrode that connects to the nozzle block (110), thereby dropping the electric potential of the corresponding negative electrode to the ground potential simultaneously, and the field emission device is additionally equipped with an auxiliary belt device (170) having an auxiliary belt (172) comprised of insulated or porous endless belt arranged in a position encircling the collector (150) to enable free rotation thereof, and an auxiliary belt driving device (174) that rotates the corresponding auxiliary belt (172) at the rotation speed corresponding to transfer speed of a long sheet (W).
Provided is a nano-fiber manufacturing device capable of always uniformizing the deposit amount of a polymer fiber, along the width direction of a long sheet. The present invention relates to a nano-fiber manufacturing device (1), which is provided with a plurality of field emission devices (20) serially arranged along the feed direction (a) of the long sheet (W), wherein each of the plurality of field emission devices (20) is provided with a reciprocal motion drive unit (201) that reciprocally moves a nozzle block (110) at a predetermined reciprocal motion cycle, along the width direction (b) of the long sheet (W), and the present invention additionally provides a reciprocal motion control device (200) that can independently control the reciprocal motion cycle of the reciprocal motion drive unit (201) for each of the field emission devices (20).
Provided is a nanofiber manufacturing device capable of resolving the problem of reducing the quality of nanofibers, even when field-emitting a polymer solution while overflowing same from a discharge outlet of an upward nozzle, by attaching polymer solids to the nanofibers. The nanofiber manufacturing device comprises: a plurality of upward nozzles (126), a nozzle block (110) having a polymer solution supply channel (114) and a polymer solution retrieval channel (120), a collector (150), and a power device, and enables field-emission of nanofibers by discharging the polymer solution from the discharge outlet of the plurality of upward nozzles (126) while overflowing the polymer solution, and the retrieval of the overflowed polymer solution for reuse as a raw material for nanofibers at the same time, and a nozzle front end portion (132) has the shape of a cylinder that was cut along the plane that crosses obliquely with the axis of the corresponding cylinder.
Provided are a nanofiber manufacturing device and a nanofiber manufacturing method capable of mass-producing a nanofiber non-woven fabric having uniform air permeability. The nanofiber manufacturing device (1) is equipped with a transfer device (10) for transferring long sheets (W) at a predetermined transfer speed (V), a field emission device (20) for accumulating nanofibers on the long sheets (W) being transferred by the transfer device (10), an air-permeability measuring device (40) for measuring the air permeability of the long sheets (W) having the nanofibers accumulated by the field emission device (20), and a transfer speed control device (50) for controlling the transfer speed (V) on the basis of the air permeability (P) measured using the air-permeability measuring device (40).
The present invention enables stable mass production of nanofibers having desired performance. The field emission device (20) is equipped with a conductive case (100), a collector (150) fitted on the case (100) through an insulation member (152), a nozzle block (110) having a plurality of nozzles (112), the nozzle block placed so as to face the collector (150), a power device (160) for permitting high voltage between the nozzle block (110) and the collector, an auxiliary belt placed in a position that encircles the collector, and an auxiliary belt driving device (174) for rotating the auxiliary belt according to the transfer speed, wherein the power device (160) has an electrode on one side of positive/negative electrodes that connects to the collector (150), and an electrode on the other side that connects to the nozzle block (110) and the case (100), and the insulation member (152) has the outer circumference thereof located on the outer side than the outer circumference of the collector, wherein the thickness (a) of the insulation member satisfies a≥6mm, and when calling the distance between the outer circumference of the insulation member (152) and the outer circumference of the collector (150), b, a+b≥50mm is satisfied.
Provided are a nanofiber manufacturing device and a nanofiber manufacturing method capable of mass-producing a nanofiber non-woven fabric having a uniform thickness. The nanofiber manufacturing device (1) is equipped with a transfer device (10) for transferring a long sheet (W) at a predetermined transfer speed (V), a field emission device (20) for accumulating nanofibers on the long sheets (W) transferred by the transfer device (10), a thickness measuring device (40) for measuring the thickness (d) of the long sheets (W) having accumulated nanofibers by the field emission device (20), and a transfer speed control device (50) for controlling the transfer speed (V) on the basis of the thickness (d) measured by the thickness measuring device (40).
Provided is a field emission device capable of stable mass-production of nanofibers having desired performance. The field emission device (20) is equipped with a case (100), a collector (150), a nozzle block (110), and a power device (160), the power device (160) having a positive electrode that connects to the collector (150), and a negative electrode that connects to the nozzle block (110) and the case (100), wherein the outer circumference of an insulation member (152) is located on the outer side than the outer circumference of the collector (150) when looking at the collector (150) from the side of the nozzle block (110), and 「a≥6mm」and 「a+b≥50mm」are fulfilled when calling the thickness of the insulation member (152), 「a」, and the distance between the outer circumference of the insulation member (152) and the outer circumference of the collector (150), 「b」.
Provided is a nanofiber manufacturing device capable of mass-producing nanofibers having uniform quality at a low manufacturing cost. The nanofiber manufacturing device is equipped with a nozzle block (110) having a plurality of upward nozzles and a polymer solution supply channel, field-emits the nanofibers while overflowing the polymer solution from the plurality of upward nozzles, and at the same time, enables retrieval and reuse of the overflowed polymer solution, and the nanofiber manufacturing device is additionally equipped with a raw material tank (200), regeneration tanks (270, 272), a middle tank (230), a first transfer device (250) for transferring the polymer solution to the regeneration tanks (270, 272), a second transfer device (210) for transferring the polymer solution to the middle tank (230), and a first and a second transfer control devices (260, 220) for controlling the transfer movements of the first and the second transfer devices.
Provided is a nanofiber manufacturing device capable of mass-producing nanofibers at a high productivity without any drop in the stability. The nanofiber manufacturing device (1) is equipped with a transfer device (10), a plurality of field emission devices (20), and a main control device (60) controlling the movements of the transfer device (10) and the plurality of field emission devices (20), wherein the main control device (60) monitors the amperage supplied by each of power devices for each of the field emission devices (20), and at the same time, when a current greater than the predetermined set amperage is detected to be supplied by one or a plurality of power devices, transmits a signal to stop the current supply from the corresponding one or the plurality of power devices, and simultaneously transmits a signal for decreasing the transfer speed of the transfer device (10) to put into predetermined range the cumulative accumulation amount of the nanofibers per unit area of accumulation on the long sheets (W).
The present invention enables appropriate maintenance of at least one of environment humidity or environment temperature of a field emission device over a long period of time. The nanofiber manufacturing device (1) is equipped with a field emission device (20) for emitting nanofibers, a air supply device (70) for supplying environment-adjusted air to the field emission device (20), and a volatile component (VOC) processing device (60) for combusting and eliminating VOC generated from the field emission device (20), wherein the air supply device (70) has a dehumidifying device for generating dehumidified air dehumidified by a dehumidifying agent dried by warm air generated by the heat of combustion generated when combusting VOC using VOC processing device (60).
The present invention relates to a device for preventing the drooping of Tomson paper for a caser, and the device comprises: a base (10) which is fixed to four places in every direction on a frame of a lower mold device (5) of a caser (1); a guide rail (11) which is fixed to the top of said base (10) by a fastening screw (12); an air cylinder (15) which is fixed to a supporter that is (13) fixed to the top of said base (10) through a fastening screw (14), and has a piston rod (16); a slider (22) which is assembled on said guide rail (11), in which a bracket (23) for assembling a support plate (27) is fixed to an upper side thereof, and in which a bolt (25) for fixing a coil spring (26) that controls an angle of the support plate (27) is assembled on the rear part of the bracket (23); a joint (17) which is fixed to the front of said slider (22), and fixes said piston rod (16) by a nut (18); the support plate (27) in which a bracket (28) fixed to the bracket (23) of said slider (22) through a fastening bolt (24) is fixed to a lower side thereof, and in which an upward bending end (27a) for supporting the Tomson paper is formed on the front; the coil spring (26) which is assembled between said slider (22) and the support plate (27), and applies a force that always lowers the upward bending end (27a) of the support plate (27); a roller (21) which is fixed by a fastening pin (20) to an upper side of a vertical part (19) that is fixed to said base (10); and a placing part (29) which is fixed to a lower side of said support plate (27) through a fastening screw (30), and in which an inclined surface (29a) is formed on a side that faces said roller (21).
A donor-acceptor compound represented by general formula (1) [wherein M is Na2, Mg, Al, Ti=O, V=O, Cr, Mn, Fe, Co, Ni, Cu, Pt, Au, or the like, or alternatively is free from metal; A is a straight-chain alkoxy group, a branched alkoxy group, or the like; B is a hydrogen atom or an alkoxy group; E is a fullerene such as C60 or C70; and n is an integer of 2 to 30]. The donor-acceptor compound can form homeotropic alignment which has little alignment defect.
C07D 487/22 - Heterocyclic compounds containing nitrogen atoms as the only ring hetero atoms in the condensed system, not provided for by groups in which the condensed system contains four or more hetero rings
H01L 51/42 - Solid state devices using organic materials as the active part, or using a combination of organic materials with other materials as the active part; Processes or apparatus specially adapted for the manufacture or treatment of such devices, or of parts thereof specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation
patents
