JP2013171724A - Organic el device manufacturing apparatus and manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an organic EL manufacturing apparatus and a manufacturing method capable of easily co-depositing on a substrate hung on an outer peripheral portion of a rotating roller.
The present invention includes a rotating roller 24 on which a base material 81 is hung on an outer periphery, a plurality of vapor deposition sources 331 and 332 for discharging a vaporizing material for vapor deposition on the base material 81, and the plurality of vapor deposition sources. And a mixer 334 that mixes the vaporized material discharged from 331 and 332 and discharges the mixed vaporized material toward the base material 81, and the mixer 334 changes a separation distance from the base material 81. The nozzle part 334c which discharges the vaporization material which can move and mixed is characterized by the above-mentioned.
[Selection] Figure 3

Description

  The present invention relates to an organic EL device manufacturing apparatus for manufacturing an organic EL (electroluminescence) device, and also relates to an organic EL device manufacturing method.

  Conventionally, a roll-to-roll process is known as a method for manufacturing an organic EL device. In such a roll-to-roll process, a belt-shaped base material wound up in a roll is continuously fed out and transported, and a vaporized material is ejected toward the base material on which the vapor deposition source is transported. This is a process in which the vaporized material is deposited on the deposition surface of the base material to form a constituent layer of the organic EL element on the base material, and then the base material is wound into a roll (see Patent Document 1).

JP 2008-287996 A

  By the way, in order to vaporize the vaporized material on the substrate, the vaporized material discharged from one vapor deposition source is directly vapor deposited on the substrate, and the vaporized materials discharged from a plurality of vapor deposition sources are mixed and vapor deposited on the substrate. There is a method (hereinafter also referred to as “co-evaporation”). And in co-evaporation, it is necessary to align each vapor deposition source so that the vaporized material discharged from each vapor deposition source mixes well on the substrate. On the other hand, it is very complicated to align the positions of the respective evaporation sources.

  Therefore, in view of such circumstances, the present invention provides an organic EL manufacturing apparatus and a manufacturing method that can be easily co-deposited on a substrate hung on the outer peripheral portion of a rotating roller. And

  An organic EL manufacturing apparatus according to the present invention is provided with a rotating roller on which a base material is hung on an outer peripheral portion, a plurality of vapor deposition sources for ejecting a vaporizing material for vapor deposition on the base material, and a plurality of vapor deposition sources. A mixing device that mixes the vaporized material and discharges the mixed vaporized material toward the substrate, the mixer being movable and mixed to change the separation distance from the substrate. A nozzle part for discharging the material is provided.

  According to the organic EL manufacturing apparatus of the present invention, when a plurality of vapor deposition sources discharge vaporized material for vapor deposition on a substrate, the mixer mixes the vaporized materials discharged from the plurality of vapor deposition sources. And a mixer co-deposits by discharging the mixed vaporization material from a nozzle part toward the base material currently hung on the outer peripheral part of a rotating roller. And the nozzle part of a mixer can change the separation distance with a base material by moving.

  The organic EL manufacturing apparatus according to the present invention further includes a vacuum chamber that houses the rotating roller and places the inside partitioned by the wall in a vacuum state, and each of the vapor deposition sources includes the vacuum chamber. The mixer may be disposed inside the vacuum chamber.

  According to the organic EL manufacturing apparatus having such a configuration, the vacuum chamber is in a vacuum state in the interior partitioned by the wall portion, and the rotating roller is accommodated in the interior. And each vapor deposition source is being fixed to the wall part of the vacuum chamber, and the mixer is arrange | positioned inside the vacuum chamber. Thereby, compared with the case where the mixing part is arrange | positioned outside the vacuum chamber, the vaporization material discharged from each vapor deposition source can be discharged from a nozzle part in a short time after mixing.

  The organic EL manufacturing apparatus according to the present invention further includes an operation tool for operating the nozzle unit to move, and the operation tool is disposed inside the vacuum chamber and connected to the nozzle unit. A connecting portion to be operated, an operating portion that is disposed and operated outside the vacuum chamber, and the connecting portion and the operating portion are connected so that the connecting portion moves when the operating portion is operated. And a connection mechanism for performing the above.

  According to the organic EL manufacturing apparatus having such a configuration, the connection portion of the operation tool is disposed inside the vacuum chamber and is connected to the nozzle portion. The operation unit of the operation tool is disposed outside the vacuum chamber. And if an operation part is operated, a connection part will move by the connection mechanism which connects a connection part and an operation part. Thereby, the nozzle part arrange | positioned inside a vacuum chamber can be moved by operating an operation part outside a vacuum chamber.

  Moreover, the manufacturing method of the organic EL device which concerns on this invention manufactures an organic EL device using the said manufacturing apparatus of an organic EL device.

  As described above, according to the present invention, there is an excellent effect that it is possible to easily perform co-evaporation on the base material hung on the outer peripheral portion of the rotating roller.

The whole perspective view of the manufacturing apparatus of the organic EL device concerning one embodiment of the present invention is shown. The principal part top view of the manufacturing apparatus of the organic EL device concerning the embodiment is shown. The principal part in-plane enlarged view in FIG. 2 of the manufacturing apparatus of the organic EL device which concerns on the embodiment is shown. The principal part internal view side view of the manufacturing apparatus of the organic EL device concerning the embodiment is shown. The whole organic EL device sectional drawing manufactured with the manufacturing device of the organic EL device concerning the embodiment is shown. The principal part internal view side view of the manufacturing apparatus of the organic EL device concerning the embodiment is shown.

  Below, one Embodiment of the manufacturing apparatus of the organic EL device which concerns on this invention is described with reference to FIGS.

  As shown in FIG. 1, an organic EL device manufacturing apparatus (hereinafter also simply referred to as “manufacturing apparatus”) 1 according to the present embodiment is transported with a transport apparatus 2 that transports a strip-shaped substrate 81 in the longitudinal direction. And a vapor deposition device 3 that vapor-deposits a vaporized material on a vapor deposition surface 811 that is one surface of the substrate 81. Further, the manufacturing apparatus 1 is not shown in FIG. 1 (see FIG. 2), but a plurality of vacuum chambers 41 in which the interior partitioned by the wall portion 411 is in a vacuum state, and each of the vacuum chambers in which the apparatuses 2 and 3 are accommodated. 4 is provided.

  The conveyance device 2 includes a base material supply unit 21 that feeds and supplies a strip-shaped base material 81 wound in a roll shape, and a plurality of rotating rollers that support the base material 81 by the base material 81 being hung on the outer peripheral portion. 22 to 28 and a base material recovery unit 29 that winds and recovers the base material 81 in a roll shape. And the base material supply part 21, each rotating roller 22-28, and the base material collection | recovery part 29 are each accommodated in the inside of each vacuum chamber 41 (refer FIG. 2). In addition, the base material 81 is conveyed in the state which turned the vapor deposition surface 811 to the side from beginning to end.

  Moreover, when the base material 81 is vapor-deposited with the vapor deposition apparatus 3, the 1st-3rd can rollers 22-24 which support the base material 81, and the base material supply part 21 are provided in the some rotation rollers 22-28. The first conveyance roller 25 that conveys the base material 81 from the first to the first can roller 22, and the second conveyance that conveys the base material 81 from the first can roller 22 to the second can roller 23. A roller 26, a third transport roller 27 that transports the base material 81 from the second can roller 23 toward the third can roller 24, and a base head from the third can roller 24 toward the base material recovery unit 29. A fourth transport roller 28 for transporting the material 81 is provided.

  The vapor deposition apparatus 3 includes a first vapor deposition section 31 that vaporizes a vaporized material toward the base material 81 supported by the first can roller 22 and a base material 81 supported by the second can roller 23. A second vapor deposition section 32 that vaporizes the vaporized material toward the substrate, and a third vapor deposition section 33 that vaporizes the vaporized material toward the base material 81 supported by the third can roller 24. In addition, each vapor deposition part 31-33 is a horizontal direction vapor deposition part arrange | positioned at the side of each can roller 22-24.

  The first vapor deposition section 31 vaporizes and discharges the vaporized material, thereby forming an anode layer vapor deposition source 311 for forming an anode layer 82 (see FIG. 5) on the vapor deposition surface 811 of the base material 81, and an anode layer vapor deposition source 311. An edge cover vapor deposition source 312 that forms an edge cover 83 (see FIG. 5) that covers the periphery of the anode layer 82 by being disposed further downstream and vaporizing and discharging the vaporized material.

  Each of the vapor deposition sources 311 and 312 is disposed such that the opening of the ejection unit is disposed on the side and opposed to the vapor deposition surface 811 of the substrate 81 in order to eject the vaporized material in the lateral direction. In addition, the vapor deposition sources 311 and 312 are arranged at positions close to the base material 81. Specifically, the vapor deposition sources 311 and 312 are arranged at positions where the distance (shortest distance) between the opening of the discharge portion of each vapor deposition source 311 and 312 and the base material 81 is 10 mm or less.

  Each vapor deposition source 311, 312 heats and vaporizes the material accommodated therein by a heating unit (not shown or numbered), and then vaporizes the material (vaporized material) of the discharge unit. It is comprised so that it may discharge toward the vapor deposition surface 811 of the base material 81 from opening.

  The second vapor deposition section 32 vaporizes and discharges the vaporized material, thereby forming a positive hole injection layer vapor deposition source 321 that forms a positive hole injection layer 841 (see FIG. 5) on the vapor deposition surface 811 of the substrate 81, A hole transport layer deposition source 322 which is disposed downstream of the hole injection layer deposition source 321 and forms a hole transport layer 842 (see FIG. 5) by vaporizing and discharging the vaporized material; A light emitting layer deposition source 323 is disposed downstream of the source 322 and forms a light emitting layer 843 (see FIG. 5) by vaporizing and discharging the vaporized material.

  The second vapor deposition section 32 is disposed downstream of the light emitting layer vapor deposition source 323, and vaporizes and discharges the vaporized material, thereby forming the electron transport layer vapor deposition source 324 that forms the electron transport layer 844 (see FIG. 5). And an electron injection layer deposition source 325 that forms an electron injection layer 845 (see FIG. 5) by vaporizing and discharging the vaporized material. That is, the second vapor deposition section 32 forms five organic EL layer constituting layers constituting the organic EL layer 84 (see FIG. 5).

  Each of the vapor deposition sources 321 to 325 is disposed such that the opening of the ejection unit is disposed on the side and opposed to the vapor deposition surface 811 of the base material 81 in order to eject the vaporized material in the lateral direction. Further, the respective vapor deposition sources 321 to 325 are arranged at positions close to the base material 81. Specifically, the respective vapor deposition sources 321 to 325 are arranged at positions where the distance (shortest distance) between the opening of the discharge part of each vapor deposition source 321 to 325 and the substrate 81 is 10 mm or less.

  And each vapor deposition source 321-325 heats the material accommodated in the inside by a heating unit (not shown and numbered), and vaporizes the vaporized material (vaporized material) of the discharge unit. It is comprised so that it may discharge toward the vapor deposition surface 811 of the base material 81 from opening.

  The 3rd vapor deposition part 33 vaporizes and discharges a vaporization material, and forms the cathode layer 85 (refer FIG. 5) in the vapor deposition surface 811 of the base material 81, The 1st and 2nd cathode layer vapor deposition source 331, 332 and a second cathode layer deposition source 332, and a sealing layer 86 (for preventing the layers 82, 84, 85 from coming into contact with air by vaporizing and discharging the vaporized material. And a sealing layer vapor deposition source 333 for forming (see FIG. 5).

  2 to 4, the third vapor deposition unit 33 mixes the vaporized materials discharged from the first and second cathode layer vapor deposition sources 331 and 332, and uses the mixed vaporized material as a base material. A mixer 334 is provided for discharging toward 81. Furthermore, the third vapor deposition unit 33 includes an operation tool 335 for operating the mixer 334.

  Each of the vapor deposition sources 331 to 333 is fixed to a flange-shaped fixing portion 411 a provided on the wall portion 411 of the vacuum chamber 41. In each of the vapor deposition sources 331 to 333, the discharge portions 331 a to 333 a at the distal end are disposed inside the vacuum chamber 41, and the base end is disposed outside the vacuum chamber 41. In addition, each of the vapor deposition sources 331 to 333 heats and vaporizes the material accommodated therein by a heating unit (not illustrated or numbered), and discharges the vaporized material (vaporized material) to the discharge units 331a to 333a. It is comprised so that it may discharge from opening of this.

  Further, in each of the vapor deposition sources 331 to 333, the openings of the discharge portions 331a to 333a are arranged on the side portions so as to discharge the vaporized material in the horizontal direction. In addition, each vapor deposition source 331-333 can contact / separate the discharge parts 331a-333b with respect to the base material 81 (can roller 24) by moving to the radial direction of the can roller 24 by the movable mechanisms 331b-333b.

  The sealing layer vapor deposition source 333 is disposed so as to face the vapor deposition surface 811 of the substrate 81. Further, the sealing layer vapor deposition source 333 is arranged at a position close to the base material 81. Specifically, the sealing layer vapor deposition source 333 is disposed at a position where the distance (shortest distance) between the opening of the discharge portion 333a of the sealing layer vapor deposition source 333 and the base material 81 is 10 mm or less.

  The mixer 334 includes a pair of vapor deposition source connection portions 334a and 334a connected to the discharge portions 331a and 332a of the first and second cathode layer vapor deposition sources 331 and 332, and vaporization discharged from the vapor deposition sources 331 and 332, respectively. A mixing unit 334b for mixing materials, a nozzle unit 334c for discharging the mixed vaporized material toward the substrate 81, and a mixing unit 334b and a nozzle unit for sending the vaporized material mixed by the mixing unit 334b to the nozzle unit 334c. And a nozzle connecting portion 334d for connecting to 334c. The mixer 334 is disposed inside the vacuum chamber 41.

  The nozzle portion 334 c is disposed so that the opening is disposed at the side and faces the vapor deposition surface 811 of the base material 81 in order to discharge the vaporized material in the lateral direction. In addition, the nozzle portion 334 c is disposed at a position close to the base material 81. Specifically, the nozzle part 334c is arranged at a position where the distance (shortest distance) between the opening of the nozzle part 334c and the base material 81 is 10 mm or less.

  The nozzle connecting portion 334d is formed with elasticity so that it can be deformed. Specifically, the nozzle connecting portion 334d is formed to expand and contract in the direction in which the nozzle portion 334c and the base material 81 face each other (the radial direction of the can roller 24). The nozzle connecting portion 334d expands and contracts to move the nozzle portion 334c, so that the separation distance between the nozzle portion 334c and the base material 81 (the outer peripheral portion of the can roller 24) can be changed. In the present embodiment, the nozzle connection portion 334d is formed in a bellows shape.

  The operation tool 335 is disposed inside the vacuum chamber 41 and connected to the nozzle unit 334c, the operation unit 335b disposed outside the vacuum chamber 41 and operated, and the operation unit 335b are operated. Thus, a connecting mechanism 335c for connecting the connecting portion 335a and the operating portion 335b is provided so that the connecting portion 335a moves. When the operation unit 335 b is operated to move in the radial direction of the can roller 24, the nozzle connection unit 334 d expands and contracts, so that the nozzle unit 334 c moves in a direction facing the base material 81.

  The inside of each vacuum chamber 41 is depressurized by a vacuum generator 42 and the inside is in a vacuum state. Adjacent vacuum chambers 41 and 41 are communicated with each other through a communication portion 43 for sequentially transporting the base material 81 in each vacuum chamber 41 so that the vacuum state in each interior is maintained. It is configured.

  The configuration of the manufacturing apparatus 1 according to this embodiment is as described above. Next, the configuration of the organic EL device 8 manufactured by the manufacturing apparatus 1 according to this embodiment will be described with reference to FIG.

  The organic EL device 8 includes a substrate 81, an anode layer 82, an edge cover 83 that covers the periphery of the anode layer 82, and a five-layer laminate so as to prevent the anode layer 82 and the cathode layer 85 from contacting each other. The organic EL layer 84, the cathode layer 85, and the sealing layer 86 that covers the layers 82, 84, 85 are provided to prevent the layers 82, 84, 85 from coming into contact with air.

  Each size (width, thickness, length) of the substrate 81 can be appropriately set according to the size of the organic EL element 80 formed on the substrate 81, the configuration of the manufacturing apparatus 1, and the like. It is not limited. The thickness of each of the layers 82, 84 to 86 and the edge cover 83 is usually designed to be several nanometers to several tens of nanometers, but is appropriately designed according to the constituent layer forming material to be used, light emission characteristics, and the like. There is no particular limitation.

  As a material for forming the base material 81, a material having flexibility so as not to be damaged when being transported is used. As such a material, for example, a metal material such as stainless steel, copper, aluminum or titanium, a non-metallic inorganic material such as thin film glass, a polyimide resin, a polyester resin, an epoxy resin, a polyurethane resin, a polystyrene resin, a polyethylene resin, or a polyamide resin Examples thereof include synthetic resin materials that are thermosetting resins and thermoplastic resins.

  Examples of the material for forming the anode layer 82 include gold, silver, and aluminum. In addition, although the anode layer 82 according to the present embodiment employs a configuration composed of one anode layer constituent layer, it is not limited to such a configuration. For example, the anode layer may be formed from one or more anode layer constituent layers.

Examples of the material for forming the edge cover 83 include silicon oxide (SiO _x ), molybdenum trioxide (MoO ₃ ), and vanadium pentoxide (V ₂ O ₅ ).

  The organic EL layer 84 is a five-layered structure including five organic EL layer constituent layers. The five organic EL layer constituting layers are a hole injection layer 841, a hole transport layer 842, a light emitting layer 843, an electron transport layer 844, and an electron injection layer 845 in this order from the anode layer 82 side.

  As a material for forming the hole injection layer 841, for example, copper phthalocyanine (CuPc), 4,4′-bis [N-4- (N, N-di-m-tolylamino) phenyl] -N-phenylamino] biphenyl ( DNTPD) and HAT-CN.

  As a forming material of the hole transport layer 842, for example, 4,4′-bis [N- (1-naphthyl) -N-phenyl-amino] biphenyl (α-NPD), N, N′-diphenyl-N, N Examples include '-bis (3-methylphenyl) -1,1'biphenyl-4,4'diamine (TPD).

  As a material for forming the light emitting layer 843, for example, 4,4′-N, N′-dicarbazonylbiphenyl doped with tris (8-hydroxyquinoline) aluminum (Alq3) or iridium complex (Ir (ppy) 3) ( CBP) and the like.

Examples of the material for forming the electron injection layer 844 include lithium fluoride (LiF), cesium fluoride (CsF), and lithium oxide (Li ₂ O).

  Examples of the material for forming the electron transport layer 845 include tris (8-hydroxyquinoline) aluminum (Alq3), bis (2-methyl-8-quinolinolato) -4-phenylphenolato-aluminum (BAlq), OXD-7 (1 , 3-bis [5- (p-tert-butylphenyl) -1,3,4-oxadiazol-2-yl]) benzene, lithium fluoride (LiF) and the like.

  In addition, although the organic EL layer 84 according to the present embodiment employs a configuration including five organic EL layer configuration layers, the configuration is not limited thereto. For example, the organic EL layer only needs to be formed of one or more organic EL layer constituent layers. Specifically, as long as the organic EL layer includes at least the light emitting layer 843, the layer configuration is not particularly limited.

  Examples of the material for forming the cathode layer 85 include alloys containing magnesium (Mg) and silver (Ag), lithium fluoride (LiF), and the like. In the present embodiment, the cathode layer 85 is formed as an Mg—Ag alloy layer. The cathode layer 85 according to the present embodiment employs a configuration composed of one cathode layer constituent layer, but is not limited to such a configuration. For example, the cathode layer only needs to be formed of one or more cathode layer constituent layers.

Examples of the material for forming the sealing layer 86 include molybdenum trioxide (MoO ₃ ), silicon oxynitride (SiNO _x ), oxygen-containing silicon carbide (SiOC), and the like. Examples of SiO _x include SiO ₂ , and examples of SiNO _x include SiNO.

  As described above, according to the organic EL manufacturing apparatus 1 according to the present embodiment, when the pair of vapor deposition sources 331 and 332 ejects a vaporization material for vapor deposition on the base material 81, the mixer 334 is connected to the vapor deposition source connection portion 334a. The vaporizing material discharged from the pair of connected vapor deposition sources 331 and 332 is mixed by the mixing unit 334b. The mixer 334 performs co-evaporation by discharging the mixed vaporized material from the nozzle portion 334 c toward the base material 81 hung on the outer peripheral portion of the can roller (rotating roller) 24.

  Further, according to the organic EL manufacturing apparatus 1 according to the present embodiment, as illustrated in FIG. 6, the nozzle portion 334 c of the mixer 334 moves by operating the operation portion 335 b by pushing or pulling. Thereby, since the nozzle part 334c contacts and separates from the base material 81, the separation distance of the nozzle part 334c and the base material 81 can be changed. Therefore, the position of the nozzle part 334c with respect to the vapor deposition surface 811 of the base material 81 can be easily adjusted.

  Further, for example, when the conveyance of the base material 81 is stopped, the nozzle portion 334c located in the vicinity of the base material 81 due to the radiant heat from the base material 81 having a high temperature (for example, 200 ° C. to 300 ° C.). There is a problem of damage. In order to solve such a problem, the nozzle portion 334 c can be easily separated from the base material 81. In this way, it is possible to easily co-deposit the base material 81 hung on the outer peripheral portion of the can roller (rotating roller) 24.

  In addition, according to the organic EL manufacturing apparatus 1 according to the present embodiment, the vacuum chamber 41 places the inside partitioned by the wall portion 411 in a vacuum state and accommodates the can roller (rotating roller) 24 therein. ing. The pair of vapor deposition sources 331 and 332 are fixed to the wall portion 411 of the vacuum chamber 41, and the mixer 334 is disposed inside the vacuum chamber 41.

  Thereby, compared with the case where the mixing part 334 is arrange | positioned outside the vacuum chamber 41, the vaporization material discharged from each vapor deposition source 331,332 is discharged from the nozzle part 334c in a short time after mixing. The

  Further, according to the organic EL manufacturing apparatus 1 according to the present embodiment, the connecting portion 335 a of the operation tool 335 is disposed inside the vacuum chamber 41 and is connected to the nozzle portion 334 c. The operation unit 335 b of the operation tool 335 is disposed outside the vacuum chamber 41. And if the operation part 335b is operated, the connection part 335a will move by the connection mechanism 335c which connects the connection part 335a and the operation part 335b.

  Accordingly, by operating the operation unit 335 b outside the vacuum chamber 41, the nozzle unit 334 c disposed inside the vacuum chamber 41 can be moved. Therefore, the position of the nozzle part 334c with respect to the vapor deposition surface 811 of the base material 81 can be adjusted more easily.

  In addition, the manufacturing apparatus and manufacturing method of the organic EL device according to the present invention are not limited to the above-described embodiments, and various changes can be made without departing from the scope of the present invention. . Moreover, it is needless to say that configurations, methods, and the like according to various modifications described below may be arbitrarily selected and employed in the configurations, methods, and the like according to the above-described embodiments.

  In the organic EL device manufacturing apparatus 1 and the manufacturing method according to the above embodiment, the configuration in which the nozzle connection portion 334d of the mixer 334 is formed in a bellows shape has been described, but the configuration is not limited thereto. For example, the nozzle connection portion 334d may have a multi-tube structure and may be configured to expand and contract by sliding each tube, or may be configured as a flexible tube having flexibility. Any configuration may be employed as long as the distance between the nozzle portion 334c and the base material 81 can be changed by moving the portion 334c relative to the mixing portion 334b.

  Moreover, in the manufacturing apparatus 1 and the manufacturing method of the organic EL device according to the above embodiment, the configuration in which the nozzle portion 334c of the mixer 334 moves by pushing or pulling or operating the operation portion 335b has been described. It is not limited to such a configuration. For example, when the operation unit 335b is rotated, the connection mechanism 335c moves the coupling unit 335a in the horizontal direction, and thus the nozzle unit 334c may move so as to change the separation distance from the base material 81. .

  Moreover, in the manufacturing apparatus 1 and the manufacturing method of the organic EL device according to the present invention, the operation tool 335 rotates the operation unit 335b when finely adjusting the position of the nozzle unit 334c when starting the manufacture. However, when the conveyance of the base material 81 is stopped, the configuration may be such that the operation unit 335b is pulled.

  For example, the operation tool 335 rotates the operation unit 335b to move the nozzle unit 334c in the horizontal direction by about 1 mm per rotation, while the operation unit 335b is pushed or pulled in the horizontal direction. The nozzle unit 334c may be moved in the horizontal direction by the amount that the operation unit 335b is moved in the horizontal direction.

  DESCRIPTION OF SYMBOLS 1 ... Organic EL device manufacturing apparatus, 2 ... Conveyance apparatus, 4 ... Vacuum chamber, 8 ... Organic EL device, 21 ... Base material supply part, 22, 23, 24 ... Rotating roller (can roller), 25, 26, 27 28 ... Rotating roller (conveying roller), 29 ... Base material recovery unit, 3 ... Deposition device, 31, 32, 33 ... Deposition unit, 41 ... Vacuum chamber, 42 ... Vacuum generator, 43 ... Communication unit, 80 ... Organic EL element 81... Base material 82 82 anode layer 83 edge cover 84 organic EL layer 85 cathode layer 86 sealing layer 311, 312, 321, 322, 323, 324, 325, 331 , 332, 333... Deposition source, 331 a, 332 a, 333 a... Discharge section, 331 b, 332 b, 333 b... Movable mechanism, 334 ... mixer, 334 a ... deposition source connection section, 334 b. c ... Nozzle connection part, 335 ... operation tool, 335a ... connection part, 335b ... operation part, 335c ... connection mechanism, 411 ... wall part, 411a ... fixed part, 811 ... vapor deposition surface, 841 ... hole injection layer, 842 ... Hole transport layer, 843 ... Light emitting layer, 844 ... Electron transport layer, 845 ... Electron injection layer

Claims (4)

A rotating roller on which a base material is hung on an outer peripheral portion, a plurality of vapor deposition sources for discharging a vaporized material for vapor deposition on the base material, and a vaporized material mixed by mixing the vaporized materials discharged from the plurality of vapor deposition sources And a mixer for discharging toward the substrate,
The mixer is provided with a nozzle unit that is movable so as to change a separation distance from the base material and that discharges the mixed vaporized material. Further comprising a vacuum chamber that houses the rotating roller and places the interior partitioned by the wall into a vacuum state;
Each deposition source is fixed to the wall of the vacuum chamber,
The organic EL device manufacturing apparatus according to claim 1, wherein the mixer is disposed inside the vacuum chamber. An operation tool for operating the nozzle unit to move,
The operation tool is disposed inside the vacuum chamber and connected to the nozzle unit, an operation unit disposed outside the vacuum chamber and operated, and the operation unit is operated. The apparatus for manufacturing an organic EL device according to claim 2, further comprising a connection mechanism that connects the connection unit and the operation unit so that the connection unit moves.   An organic EL device is manufactured using the manufacturing apparatus of the organic EL device of any one of Claims 1-3, The manufacturing method of the organic EL device characterized by the above-mentioned.

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