JP2004121957A - Droplet discharging device and its workpiece replacing method, electro-optical device, manufacturing method of electro-optical device and electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a droplet discharging device with shortened cycle time in work treatment as a whole, and a workpiece replacing method. <P>SOLUTION: This droplet discharging device 1 treats a work by relatively moving a functional droplet discharging nozzle head 8 to the workpiece W and selectively discharging the functional droplets from the head 8. The device is equipped with a first workpiece table 21A and a second workpiece table 21B respectively placing workpiece W, and a workpiece replacement means 3 for alternately placing the treated workpiece W and the untreated workpiece W to the first and the second workpiece tables 21A and 21B. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a droplet discharging apparatus that discharges a functional liquid, such as an ink jet head, onto a work such as a substrate by using a functional droplet discharging head, a method of replacing the work, an electro-optical device, and a method of manufacturing an electro-optical device. And electronic equipment.
[0002]
[Prior art]
In a conventional droplet discharge apparatus that discharges functional droplets while drawing a functional droplet while relatively moving a functional droplet discharge head to a workpiece such as a substrate on a set table, the processing is performed after the drawing operation is completed ( The (drawn) work is moved to the replacement position, and the work transfer mechanism replaces the work before processing (new). In this case, the work transfer mechanism has, for example, a supply cassette and a collection cassette, and after the work after processing is transferred from the set table to the collection cassette by the transfer robot, the work before processing is transferred from the supply cassette to the set table. Transfer to The work transferred to the set table is precisely positioned (aligned) using a recognition camera or the like.
[0003]
Note that there is Japanese Patent Application No. 2002-30005 (FIG. 6, paragraphs [0069] to [0072]) as an undisclosed prior application by the present applicant, but no prior art document disclosed is found.
[0004]
[Problems to be solved by the invention]
In such a conventional droplet discharge device, the drawing operation is stopped when the work is replaced (replaced), so that the ratio of the work replacement time (including the alignment) to the drawing time is relatively high. However, even if the drawing time is reduced, there is a problem that it is difficult to shorten the tact time of the work processing as a whole.
[0005]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a droplet discharge device, a work replacement method thereof, an electro-optical device, a method of manufacturing an electro-optical device, and an electronic device that can shorten the tact time in the work processing as a whole.
[0006]
[Means for Solving the Problems]
The droplet discharging apparatus of the present invention is a droplet discharging apparatus that performs a work process by discharging a functional droplet from a functional droplet discharging head while relatively moving the functional droplet discharging head with respect to a workpiece. A first work table and a second work table, respectively, and a work exchanging means for alternately replacing the first work table and the second work table with the work after the processing and the work before the processing. It is characterized by having.
[0007]
In this case, it is preferable that the first work table and the second work table are configured as moving tables that extend in parallel with each other and move the work in the extending direction in the work processing.
[0008]
According to these configurations, while the work set on the first work table is being processed by the functional liquid droplet ejection head, the work after processing and the work before processing are performed on the second work table. Replace (replace). Similarly, while the workpiece set on the second work table is being processed, the post-processing work and the pre-processing work are exchanged (exchanged) on the first work table. That is, using the first and second work tables, work processing and work exchange are performed simultaneously and in parallel. Therefore, there is no need to stop the work processing when the work is replaced.
When the first work table and the second work table are each constituted by a simple set table (not movable), the work set positions are shifted from each other, and when replacing the work, the functional liquid droplet ejection head or the like is used. It is preferable that the movable part of the camera does not get in the way.
[0009]
In this case, it is preferable that the work exchange means includes a work supply mechanism that supplies the work before processing and a work collection mechanism that collects the work after processing, which are configured independently of each other.
[0010]
According to this configuration, the work exchange means can be simplified, and the work supply mechanism and the work collection mechanism can be appropriately distributed and arranged.
[0011]
In this case, the first work table and the second work table each have a work supply position at one end in the movement direction of the work and a collection position of the work at the other end, respectively. Preferably, the work collection mechanism faces the respective supply positions of the first work table and the second work table, and the work collection mechanism faces the respective collection positions of the first work table and the second work table.
[0012]
According to this configuration, the work supply mechanism and the work collection mechanism can be arranged so as to sandwich the first work table and the second work table from both sides in the extending direction. Can be structurally prevented, and the work supply mechanism and the work recovery mechanism can be arranged in a well-balanced manner.
[0013]
In this case, the apparatus further includes a head moving table on which the functional liquid droplet ejecting head is mounted and which moves the functional liquid droplet ejecting head in a direction intersecting with the moving direction of the work. In addition, it is preferable to move the functional liquid ejection head so as to pass through a substantially intermediate position in the extending direction of the first work table and the second work table.
[0014]
According to this configuration, the workpiece processing can be performed at a substantially intermediate position in the extending direction of the first work table and the second work table, and the workpiece can be replaced at a position deviated left and right from this. In other words, the work area used for work processing and the work area used for work exchange can be sufficiently separated, and interference between the work exchange means and a movable part such as a functional liquid droplet ejection head can be minimized.
[0015]
In these cases, the work supply mechanism includes a supply work cassette for accommodating the work before processing, a supply robot for transferring the work in the supply work cassette to the first work table and the second work table, and a supply robot. And a supply robot moving mechanism for moving the workpiece between a position where the work is taken out from the supply work cassette, a position facing the supply position of the first work table, and a position facing the supply position of the second work table. Is preferred.
[0016]
According to this configuration, when supplying the work to the first work table, the supply robot is moved to the supply work cassette, the work is taken out from the supply work cassette, and then the supply robot is moved to the first work table. Then, the work is placed on this. Similarly, when supplying a work to the second work table, the supply robot is moved to the supply work cassette, the work is taken out from the supply work cassette, and then the supply robot is moved to the second work table. The work is placed on this. Since the supply robot is moved in this way, the supply robot itself can be configured with a simple movement.
[0017]
In this case, it is preferable that the supply work cassette and the supply robot moving mechanism are arranged in a row in a direction intersecting the extending direction of the first work table and the second work table.
[0018]
According to this configuration, the work supply mechanism can be arranged along the apparatus main body, and the apparatus can be made compact as a whole.
[0019]
In these cases, the work collection mechanism includes a collection work cassette that stores the processed work, a collection robot that transfers the work of the first work table and the second work table to the collection work cassette, and a collection robot. A collection robot moving mechanism for moving between a position where the work is transferred to the collection work cassette, a position facing the collection position of the first work table, and a position facing the collection position of the second work table. Is preferred.
[0020]
According to this configuration, when collecting the work from the first work table, the collection robot is moved to the first work table, the work is handled, and then the supply robot is moved to the supply work cassette. To put the work. Similarly, when collecting the work from the second work table, the collection robot is moved to the second work table, the work is handled, and then the supply robot is moved to the supply work cassette, and the work is transferred to the supply work cassette. Let go.
[0021]
In this case, it is preferable that the collection work cassette and the collection robot moving mechanism are arranged in a row in a direction intersecting the extending direction of the first work table and the second work table.
[0022]
According to this configuration, the work collection mechanism can be arranged along the apparatus main body, and the apparatus can be made compact as a whole.
[0023]
In the method for exchanging a work of the droplet discharge apparatus according to the present invention, a work process is performed by selectively discharging functional droplets from the functional droplet discharge head while moving the functional droplet discharge head relative to the work. In a method of exchanging a work of a droplet discharge device, a first work table and a second work table each having a work mounted thereon are used, and while the work is being processed by the first work table, the processed work is performed on the second work table. It is assumed that the work is replaced with the work before the processing, and the work after the processing and the work before the processing are replaced on the first work table while the work processing is performed by the second work table. Features.
[0024]
According to this configuration, the work processing and the work exchange are performed in parallel using the first and second work tables, so that there is no need to stop the work processing at the time of the work exchange.
[0025]
According to another aspect of the invention, there is provided an electro-optical device including the above-described droplet discharge device, wherein a functional droplet is discharged from a functional droplet discharge head onto a workpiece to form a film forming unit.
[0026]
Similarly, a method of manufacturing an electro-optical device according to the present invention is characterized in that a functional droplet is discharged from a functional droplet discharging head onto a work using the above-described droplet discharging device to form a film forming section. .
[0027]
According to these configurations, the electro-optical device itself can be efficiently manufactured because the device is manufactured using the droplet discharge device capable of performing the work processing in a short time. In addition, as the electro-optical device, a liquid crystal display device, an organic EL (Electro-Luminescence) device, an electron emission device, a PDP (Plasma Display Panel) device, an electrophoretic display device, and the like are considered. The electron emission device is a concept including a so-called FED (Field Emission Display) device. Further, as the electro-optical device, devices for forming a metal wiring, forming a lens, forming a resist, and forming a light diffuser can be considered.
[0028]
According to still another aspect of the invention, an electronic apparatus includes the above-described electro-optical device or an electro-optical device manufactured by the above-described method for manufacturing an electro-optical device.
[0029]
In this case, as the electronic device, various electric products other than a mobile phone and a personal computer equipped with a so-called flat panel display correspond thereto.
[0030]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a droplet discharge device, an electro-optical device, and an electronic apparatus according to the invention will be described with reference to the accompanying drawings. The droplet discharge apparatus according to the present embodiment uses a functional droplet discharge head to discharge functional droplets onto a substrate W, which is a work, to form a desired film formation unit on the substrate (work processing) ( Details will be described later). As shown in FIG. 1, the droplet discharge device 1 of the embodiment includes an apparatus main body 2 that performs a work process, and a work exchange unit 3 that is attached to the apparatus main body 2 and that exchanges a work.
[0031]
The apparatus main body 2 includes a machine 5, a drawing device 6 widely mounted on the entire area of the machine 5, and a head function recovery device 7 mounted on an end of the machine 5. The work processing is performed by the device 6, and the function recovery process (maintenance) of the functional droplet discharge head 8 provided in the drawing device 6 is performed by the head function recovery device 7. The work exchange means 3 has a work supply mechanism 10 for supplying the work W to the drawing apparatus 6 and a work collection mechanism 11 for collecting the work W from the drawing apparatus 6. The work supply mechanism 10 and the work collection mechanism 11 , The machine base (apparatus main body 2) 5 is provided on both sides thereof so as to sandwich it.
[0032]
The drawing device 6 includes a first X-axis table 21A that is a first work table, a second X-axis table 21B that is a second work table arranged close to and parallel to the first X-axis table 21A, Move to the Y-axis table 22, which is orthogonal to the two X-axis tables 21A and 21B, and straddles the first and second X-axis tables 21A and 21B and the head function recovery device 7, and to the Y-axis table 22. The main carriage 23 includes a main carriage 23 that is freely mounted and a head unit 24 that is suspended from the main carriage 23. A plurality of (four in the drawing) functional droplet discharge heads 8 are mounted on the head unit 24 via a sub-carriage 25. The work W in this case is a substrate, and is detachably mounted on the first and second X-axis tables 21A and 21B, respectively.
[0033]
The head function recovery device 7 includes a moving table 31 mounted on the machine base 5, a cap unit 32 and a wiping unit 33 mounted on the moving table 31. The cap unit 32 has a function of a flushing box that forcibly sucks the functional liquid from the functional droplet discharge head 8 and receives the discharge of the functional liquid from all the nozzles of the functional droplet discharge head 8. The wiping unit 33 mainly wipes the nozzle surface of the functional liquid droplet ejection head 8 after suctioning the functional liquid.
[0034]
The cap unit 32 is provided with, for example, a cap assembly incorporating a plurality (four) of caps corresponding to the plurality (four) of the functional droplet discharge heads 8 so as to be able to move up and down. When filling the functional liquid discharge head 8) with the functional liquid or removing the functional liquid thickened in the functional liquid droplet discharge head 8, each cap is brought into close contact with the functional liquid droplet discharge head 8, , Perform pump suction. Further, when the discharge (drawing) of the functional liquid is stopped, each cap is slightly separated from each functional liquid droplet discharge head 8, and flushing (discharge discharge) is performed.
[0035]
In the wiping unit 33, for example, a wiping sheet is provided so as to be able to be fed out and taken up freely. The nozzle surface of the ejection head 8 is wiped.
[0036]
Although not shown in the drawing, the droplet discharge device 1 includes a functional liquid supply mechanism for supplying a functional liquid to each functional droplet discharge head 8 and the above-described drawing device 6 and functional droplet discharge head 8. A control means (to be described later) 13 for integrally controlling the constituent devices is incorporated.
[0037]
Each of the first and second X-axis tables 21A and 21B has a motor-driven X-axis slider 41 constituting a drive system in the X-axis direction, and a set table 42 including a suction table 43 and a θ table 44. Is mounted movably. Similarly, the Y-axis table 22 has a motor-driven Y-axis slider 46 constituting a drive system in the Y-axis direction, and the main carriage 23 is movably mounted thereon via a θ table 47, It is configured.
[0038]
In this case, the first and second X-axis tables 21A, 21B are directly supported on the machine base 5, while the Y-axis table 22 is supported by front and rear columns 49, 49 erected on the machine base 5. Have been. Further, the first X-axis table 21A, the second X-axis table 21B, and the head function recovery device 7 are arranged in parallel with each other in the X-axis direction, and are located at a substantially intermediate position (directly above the extending direction of these devices). ), The Y-axis table 22 extends in the Y-axis direction.
[0039]
Then, the Y-axis table 22 has the head unit (functional liquid ejection head 8) 24 mounted thereon mounted on the function recovery area 51 located immediately above the head function recovery device 7 and the function recovery area 51 immediately above the first X-axis table 21A. It is appropriately moved between the located first drawing area 52 and the second drawing area 53 located immediately above the second X-axis table 21B. That is, when performing the function recovery of the functional droplet discharge head 8, the Y-axis table 22 faces the head unit 24 to the function recovery area 51 and performs drawing on the work W introduced into the first X-axis table 21 </ b> A. Then, when the head unit 24 faces the first drawing area 52 and draws on the work W introduced into the second X-axis table 21B, the head unit 24 faces the second drawing area 53.
[0040]
On the other hand, the left ends of the first and second X-axis tables 21A and 21B with the Y-axis table 22 interposed therebetween are used to mount (set) the work W on the first and second X-axis tables 21A and 21B, respectively. The supply positions 55, 55 are provided, and the right ends are collection positions 56, 56 for removing the workpiece W from the first and second X-axis tables 21A, 21B, respectively. When the first and second X-axis tables 21A and 21B receive the supply of the work W from the work supply mechanism 10, the set table 42 is moved to the supply position 55, and the work W is transferred to the work collection mechanism 11. In this case, the set table 42 on which the work W is mounted is moved to the collection position 56, respectively.
[0041]
Each supply position 55 is provided with a pair of work recognition cameras 58, 58, and the work W supplied to the set table (the suction table 44) 42 by the pair of work recognition cameras 58, 58. The two reference marks are simultaneously recognized, and the workpiece W is aligned based on the recognition result. More specifically, based on this recognition result, the angle correction of the functional droplet discharge head (head unit 24) 8 is performed by the θ table 44 of the set table 42, and the X-axis direction in the discharge pattern data described later. And correction of the position data in the Y-axis direction.
[0042]
In the droplet discharge device 1 according to the embodiment, the movement of the work W in the X-axis direction is defined as main scanning, and the movement of the functional droplet discharging head (head unit 24) 8 in the Y-axis direction is defined as sub-scanning. Drawing is performed based on the ejection pattern data stored in the means 13.
[0043]
For example, when performing drawing on the work W introduced into the first drawing area 52, the functional droplet discharge head (head unit 24) 8 faces the first drawing area 52, and the first X-axis table 21A is used. The functional droplet discharge head 8 is driven (selective discharge of functional droplets) in synchronization with the main scanning and the sub-scanning of the Y-axis table 22. Similarly, when performing drawing on the work W introduced into the second drawing area 53, the functional droplet discharge head (head unit 24) 8 faces the second drawing area 53 and the second X-axis table 21B The functional droplet discharge head 8 is driven (selective discharge of the functional droplet) in synchronization with the main scanning by the sub scanning of the Y-axis table 22.
[0044]
When performing the function recovery of the functional droplet discharge head 8, the cap unit 32 is moved to the function recovery area 51 by the moving table 31, and the head unit 24 is moved to the function recovery area 51 by the Y-axis table 22. Flushing or pump suction of the functional droplet discharge head 8 is performed. When the pump suction is performed, the wiping unit 33 is subsequently moved to the function recovery area 51 by the moving table 31, and the wiping of the functional liquid droplet ejection head 8 is performed.
[0045]
On the other hand, the work supply mechanism 10 of the work exchange means 3 stores the supply work cassette 61 for accommodating the work W before processing and the work W in the supply work cassette 61 into the first X-axis table 21A and the second X-axis table 21B. And a supply robot moving mechanism 63 with a base for moving the supply robot 62 between the supply work cassette 61 and the first and second X-axis tables 21A and 21B. have. In this case, the supply work cassette 61 and the supply robot moving mechanism 63 are arranged in the Y-axis direction along the left end of the machine base 5.
[0046]
The supply work cassette 61 has a multistage shelf in a cassette case, and stores a large number of works W before processing. Although not shown in detail, the supply robot moving mechanism 63 includes, for example, a slider on which the supply robot 62 is mounted, a pair of slide guides for guiding the movement (Y-axis direction) of the slider, and a ball screw screwed to the slider. , A motor for rotating the ball screw in the forward and reverse directions, and a mount on which these are mounted. When the motor rotates forward and backward, the slider is guided by the slide guide and moves in the Y-axis direction (front-back direction).
[0047]
As shown in FIG. 2, the supply robot 62 supports a thin fork-shaped robot hand 65 for adsorbing and mounting (handling) the workpiece W, and supports the robot hand 65 and moves the robot hand 65 freely in a horizontal plane (movable forward and backward). The robot arm 66 includes a robot arm 66, a vertical movement mechanism 67 for vertically moving the robot arm 66, and a stand 68 having a built-in vertical movement mechanism 67. The supply robot 62 is fixed on the slider of the supply robot moving mechanism 63 at the stand 68.
[0048]
When the work (work W before processing) W is supplied to the first and second X-axis tables 21A and 21B, first, the supply robot 62 is moved by the supply robot moving mechanism 63 to take out the work from the supply work cassette 61. Move to position. Next, the supply robot 62 is driven to take out the work W stored in a desired shelf. Here, when supplying the work W to the first X-axis table 21A, the supply robot 62 is moved by the supply robot moving mechanism 63 to a position facing the supply position 55 of the first X-axis table 21A. Further, before and after this movement, the supply robot 62 turns the robot arm 66 by 90 ° to set the workpiece W to the set posture. Finally, the supply robot 62 transfers the work W onto the set table 42 that has been moved to the supply position 55. Also, when the workpiece W is supplied to the second X-axis table 21B, the operation is exactly the same.
[0049]
The work collection mechanism 11 includes a collection work cassette 71 that stores the processed work W, a collection robot 72 that transfers the work W of the first X-axis table 21A and the second X-axis table 21B to the collection work cassette 71, And a collection robot moving mechanism 73 with a base for moving the collection robot 72 between the collection work cassette 71 and the first and second X-axis tables 21A and 21B. Similarly to the above, the collection work cassette 61 and the collection robot moving mechanism 63 are arranged in a row in the Y-axis direction along the right end of the machine base 5. Note that the collection work cassette 71, the collection robot 72, and the collection robot moving mechanism 73 are the same as the supply work cassette 61, the supply robot 62, and the supply robot moving mechanism 63 except that the work W after processing is handled. Since they have a structure, description of these structures is omitted here.
[0050]
When the work (processed work W) W is to be collected from the first X-axis table 21A, for example, by the work collection mechanism 11, first, the collection robot 72 is moved by the collection robot moving mechanism 73 to collect the first X-axis table 21A. The workpiece W is moved to a position facing the position 56, and the work W is received from the set table 42 moving to the collection position 56. Next, the collection robot 72 is moved by the collection robot moving mechanism 73 to a position where the work W of the collection work cassette 71 is accommodated. In addition, before and after this movement, the collection robot 72 turns the robot arm 66 by 90 ° to bring the work W into the accommodation posture. Finally, the collection robot 72 stores the work W on a desired shelf of the collection work cassette 71. Also, when the work W is collected from the second X-axis table 21B, the operation is exactly the same.
[0051]
The control unit 13 includes a control unit 81 that controls various operations of the droplet discharge device 1, as shown in FIG. The control unit 81 includes a CPU 82 for performing various controls, a ROM 83, a RAM 84, and an interface 85, and these are connected to each other via a bus 86. The ROM 83 has an area for storing control programs and control data processed by the CPU 82. The RAM 84 is used as various work areas for control processing. The interface 85 incorporates a logic circuit that supplements the function of the CPU 82 and handles interface signals with peripheral circuits.
[0052]
The interface 85 includes the first and second X-axis tables 21A and 21B, the Y-axis table 22, each functional droplet discharge head 8, the head function recovery device 7, the work supply mechanism 10, and the work recovery mechanism 11, Each is connected via a driver (not shown). Further, work recognition cameras (two sets, four in total) 58, 58 are connected to the interface 85 as a detection unit 87. The CPU 82 inputs various detection signals, various commands, and various data via the interface 85 according to the control program in the ROM 83, controls various data (ejection pattern data) in the RAM 84, and the like, and Outputs various control signals.
[0053]
That is, the CPU 82 controls the ejection drive of the functional liquid droplet ejection head 8 and controls the movement of the first and second X-axis tables 21A and 21B and the Y-axis table 22 to draw on the work W ( While exchanging the work, the work supply mechanism 10 and the work collection mechanism 11 are controlled. When the work W is set, the CPU 82 performs angle correction and discharge pattern data correction in the first and second X-axis tables 21A and 21B based on the recognition result of the work recognition camera 58. Further, the CPU 82 controls the cap unit 32, the wiping unit 33, and the like of the head function recovery device 7 at the time of regular maintenance of the functional liquid droplet ejection head 8.
[0054]
Next, a control method of the drawing operation and the work exchanging operation by the control means 13 will be described. As shown in FIG. 1, when the work W before processing is introduced into the first drawing area 52 of the first X-axis table 21A, the head unit (functional droplet discharge head 8) 24 faces the work W and the work W Drawing on W (selective ejection of functional droplets) is performed.
[0055]
On the other hand, in parallel with this drawing operation, in the second X-axis table 21B, the processed work W moves to the collection position 56, where the collection robot 72 of the work collection mechanism 11 faces and collects the work W. In the work cassette 71. When the work W is transferred to the collection robot 72, the second X-axis table 21A moves the set table 42 to the supply position 55. Here, the supply robot 62 transfers the work W transported from the collection work cassette 61 to the set table 42.
[0056]
When the work W is set on the set table 42, the work recognition camera 58 recognizes the work W and performs various corrections. When the setting of the work W is completed in this way, the second X-axis table 21B moves the work W to the second drawing area 53 via the set table 42, and sets the work W in a standby state.
[0057]
Eventually, when the drawing in the first drawing area 52 is completed, the Y-axis table 22 moves the head unit 24 to the second drawing area 53 and starts a drawing operation on a new work W. When the head unit 24 moves from the first drawing area 52 in this way, the work W after drawing moves to the collection position 56 to collect the work W, and then the work W A supply of W is made.
[0058]
As described above, when the drawing operation on the work W is performed by the first X-axis table 21A, the work W is replaced (replaced) by the second X-axis table 21B. The operation can be continued. Therefore, unlike the related art, it is not necessary to stop the drawing operation for exchanging the work, and the takt time in the work processing can be significantly reduced as a whole, and the productivity can be improved.
[0059]
In the droplet discharge device 1 of the embodiment, the time required for drawing a specific work (substrate) W (drawing time) is approximately 35 seconds, and the time required for replacing the work W (replacement time) at that time is approximately 35 seconds. 25 seconds. For this reason, by simultaneously performing the drawing operation and the work exchange operation as described above, the tact time can be reduced from 60 seconds to 35 seconds.
[0060]
Here, a case where the above-described droplet discharge device 1 is applied to the manufacture of a liquid crystal display device will be described. FIG. 4 illustrates a cross-sectional structure of the liquid crystal display device 301. As shown in the figure, the liquid crystal display device 301 is composed of an upper substrate 311 and a lower substrate 312 having a transparent conductive film (ITO film) 322 and an alignment film 323 formed on the opposing surface mainly of a glass substrate 321; A large number of spacers 331 interposed between the upper and lower substrates 311 and 312, a sealing material 332 for sealing between the upper and lower substrates 311 and 312, and a liquid crystal 333 filled between the upper and lower substrates 311 and 312 are provided. A phase substrate 341 and a polarizing plate 342 a are stacked on the back surface of the substrate 311, and a polarizing plate 342 b and a backlight 343 are stacked on the back surface of the lower substrate 312.
[0061]
In a normal manufacturing process, the upper substrate 311 and the lower substrate 312 are separately manufactured by patterning the transparent conductive film 322 and applying the alignment film 323, respectively, and then the spacer 331 and the sealing material 332 are formed on the lower substrate 312. In this state, the upper substrate 311 is attached. Next, the liquid crystal 333 is injected from the inlet of the sealant 332, and the inlet is closed. After that, the phase substrate 341, the polarizing plates 342a and 342b, and the backlight 343 are stacked.
[0062]
The droplet discharge device 1 of the embodiment can be used, for example, for forming the spacer 331 and for injecting the liquid crystal 333. Specifically, a spacer material (for example, an ultraviolet curable resin or a thermosetting resin) or a liquid crystal that forms a cell gap is introduced as a functional liquid, and these are uniformly discharged (applied) to predetermined positions. First, the lower substrate 312 on which the sealing material 332 is printed in a ring shape is set on the suction table 42, and the spacer material is discharged onto the lower substrate 312 at coarse intervals, and the spacer material is solidified by irradiating ultraviolet rays. Next, a predetermined amount of liquid crystal 333 is uniformly discharged and injected into the inside of the sealing material 332 of the lower substrate 312. Thereafter, the separately prepared upper substrate 311 and the lower substrate 312 coated with a predetermined amount of liquid crystal are introduced into a vacuum and bonded together.
[0063]
As described above, since the liquid crystal 333 is uniformly applied (filled) in the cell before the upper substrate 311 and the lower substrate 312 are bonded to each other, the liquid crystal 333 does not spread to details such as corners of the cell. Can be solved.
[0064]
By using an ultraviolet curable resin or a thermosetting resin as the functional liquid (material for the sealant), the above-described sealant 332 can be printed by the droplet discharge device 1. Similarly, by introducing a polyimide resin as the functional liquid (alignment film material), the alignment film 323 can be formed by the droplet discharge device 1.
[0065]
As described above, in the manufacture of the liquid crystal display device 301, it is assumed that various types of functional liquids are introduced. However, in the above-described droplet discharge device 1, the functional liquid is precisely dispensed by the special form of the functional droplet discharge head 30. Since the liquid crystal display device 301 can be discharged (landed), the liquid crystal display device 301 can be manufactured accurately and stably.
[0066]
By the way, the above-described droplet discharge device 1 can be used for manufacturing various electro-optical devices (devices) in addition to the above-described liquid crystal display device 301 mounted on an electronic device such as a mobile phone or a personal computer. . That is, the droplet discharge device 1 of the present embodiment can be applied to the manufacture of an organic EL device, an FED device (electron emission device), a PDP device, an electrophoretic display device, and the like.
[0067]
An example in which the above-described droplet discharge device 1 is applied to the manufacture of an organic EL device will be briefly described. As shown in FIG. 5, the organic EL device 401 includes a substrate 421, a circuit element portion 422, a pixel electrode 423, a bank portion 424, a light emitting element 425, a cathode 426 (a counter electrode), and a sealing substrate. An organic EL element 411 composed of a wiring 427 and a wiring of a flexible substrate (not shown) and a driving IC (not shown) are connected. The circuit element portion 422 is formed on the substrate 421, and the plurality of pixel electrodes 423 are arranged on the circuit element portion 422. A bank 424 is formed between the pixel electrodes 423 in a lattice pattern, and a light emitting element 425 is formed in a concave opening 431 formed by the bank 424. The cathode 426 is formed over the entire upper surface of the bank portion 424 and the light emitting element 425, and a sealing substrate 427 is stacked on the cathode 426.
[0068]
In the manufacturing process of the organic EL device 401, after the bank portion 424 is formed at a predetermined position on the circuit element portion 422 and the substrate 421 (work W) on which the pixel electrode 423 is formed, the light emitting element 425 is appropriately Is performed, and then a light emitting element 425 and a cathode 426 (a counter electrode) are formed. Then, the sealing substrate 427 is laminated on the cathode 426 and sealed to obtain the organic EL element 411. Then, the cathode 426 of the organic EL element 411 is connected to the wiring of the flexible substrate and connected to the driving IC. The organic EL device 401 is manufactured by connecting the wiring of the circuit element portion 422.
[0069]
The droplet discharge device 1 is used for forming the light emitting element 425. Specifically, a light emitting element material (functional liquid) is introduced into the functional droplet discharge head 30, and the light emitting element material is discharged corresponding to the position of the pixel electrode 423 on the substrate 421 on which the bank portion 424 is formed. By drying this, the light emitting element 425 is formed. In the formation of the pixel electrode 423 and the cathode 426 described above, the liquid crystal material can be formed by using the liquid material corresponding to each of them.
[0070]
In addition, for example, in the method of manufacturing an electron emission device, a fluorescent material of each color of R, G, and B is introduced into the plurality of functional droplet discharge heads 30, and the plurality of functional droplet discharge heads 30 perform main scanning and sub-scanning to obtain fluorescent light. A material is selectively discharged to form a large number of phosphors on the electrodes.
[0071]
In the method of manufacturing the PDP device, fluorescent materials of R, G, and B colors are introduced into the plurality of functional droplet discharge heads 30, and the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned to selectively use the fluorescent material. To form phosphors in a large number of concave portions on the rear substrate.
[0072]
In the method of manufacturing the electrophoretic display device, the electrophoretic material of each color is introduced into the plurality of functional droplet discharge heads 30, the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned, and the electrophoretic material is selectively selected. By discharging, a phosphor is formed in each of the many concave portions on the electrode. The electrophoretic body composed of the charged particles and the dye is preferably encapsulated in a microcapsule.
[0073]
Further, as other electro-optical devices, devices such as metal wiring formation, lens formation, resist formation, and light diffuser formation can be considered. The droplet discharge device 1 of the present embodiment is also applicable to these various manufacturing methods. Applicable.
[0074]
For example, in the metal wiring forming method, a liquid metal material is introduced into a plurality of functional droplet discharge heads 30, and the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned to selectively discharge the liquid metal material. Then, a metal wiring is formed on the substrate. For example, these devices can be manufactured by applying the present invention to a metal wiring connecting the driver and each electrode in the above-described liquid crystal display device and a metal wiring connecting the TFT and the like to each electrode in the organic EL device. It goes without saying that the present invention can be applied to general semiconductor manufacturing techniques other than this kind of flat panel display.
[0075]
In the method of forming a lens, a lens material is introduced into the plurality of functional droplet discharge heads 30, the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned, and the lens material is selectively discharged to form a lens on the transparent substrate. A number of microlenses are formed on the substrate. For example, the present invention can be applied to the case where a device for beam convergence in the FED apparatus is manufactured. Further, the present invention is also applicable to various optical device manufacturing techniques.
[0076]
In the lens manufacturing method, a translucent coating material is introduced into the plurality of functional droplet discharge heads 30, and the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned to selectively discharge the coating material. Then, a coating film is formed on the surface of the lens.
[0077]
In the resist forming method, a resist material is introduced into the plurality of functional droplet discharge heads 30, the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned, and the resist material is selectively discharged onto the substrate. A photoresist having a shape is formed. For example, the present invention can be widely applied to the application of a photoresist in a photolithography method which is a main body of a semiconductor manufacturing technique, in addition to the formation of a bank in the above-described various display devices.
[0078]
In the light diffuser forming method, a light diffusion material is introduced into the plurality of functional droplet discharge heads 30, the plurality of functional droplet discharge heads 30 are main-scanned and sub-scanned, and the light diffusion material is selectively discharged. A number of light diffusers are formed on a substrate. Also in this case, it is needless to say that the present invention can be applied to various optical devices.
[0079]
As described above, there is a possibility that various types of functional liquids may be introduced into the droplet discharge device 1. However, by using the above-described droplet discharge device 1 for manufacturing various electro-optical devices (devices), the The optical device can be manufactured accurately and stably.
[0080]
【The invention's effect】
According to the droplet discharge device and the work replacement method of the present invention, the work processing and the work replacement are performed simultaneously in parallel using the first and second work tables. There is no need to stop the processing, and the takt time in the work processing can be shortened as a whole.
[0081]
According to the electro-optical device and the electronic apparatus of the present invention, since the workpiece is manufactured by the droplet discharge device capable of efficiently performing the work processing in a short time, a high-quality and low-cost electro-optical device can be provided.
[Brief description of the drawings]
FIG. 1 is a plan view of a droplet discharge device according to an embodiment of the present invention.
FIG. 2 is a structural diagram of a supply robot (recovery robot) of a workpiece exchange unit.
FIG. 3 is a block diagram illustrating a control unit of the droplet discharge device.
FIG. 4 is a sectional view of a liquid crystal display device manufactured by the droplet discharge device of the present invention.
FIG. 5 is a cross-sectional view of an organic EL device manufactured by the droplet discharge device of the present invention.
[Explanation of symbols]
1 droplet discharge device 2 device body
3 Work exchange means 6 Drawing device
7 Head function recovery device 8 Functional droplet discharge head
10 Work supply mechanism 11 Work collection mechanism
13 control means 21A first X-axis table
21B 2nd X-axis table 22 Y-axis table
24 head unit 42 set table
51 Function recovery area 52 First drawing area
53 Second drawing area 55 Work supply position
56 Work collection position 61 Work cassette for supply
62 Supply robot 63 Supply robot moving mechanism
71 Work cassette for collection 72 Collection robot
73 Collection robot moving mechanism 81 Control unit
82 CPU 301 Liquid crystal display device
401 Organic EL device W substrate

Claims (13)

In a droplet discharging apparatus that performs a work process by discharging a functional droplet from the functional droplet discharging head while relatively moving the functional droplet discharging head with respect to the workpiece,
A first work table and a second work table each having a work mounted thereon, and a work exchange means for alternately replacing the work after the processing and the work before the processing with respect to the first work table and the second work table; And a droplet discharge device. 2. The apparatus according to claim 1, wherein the first work table and the second work table extend in parallel with each other, and are configured as moving tables that respectively move the work in the extending direction in the work processing. 3. The droplet discharge device according to the above. 3. The droplet discharging apparatus according to claim 2, wherein the work exchange means includes a work supply mechanism that supplies a work before processing and a work collection mechanism that collects the work after processing, which are configured independently of each other. apparatus. The first work table and the second work table each have a work supply position at one end in the movement direction of the work and a work collection position at the other end,
The work supply mechanism faces respective supply positions of the first work table and the second work table,
4. The droplet discharge device according to claim 3, wherein the work collection mechanism faces the respective recovery positions of the first work table and the second work table. 5. A head moving table mounted with the functional liquid droplet discharging head and configured to move the functional liquid droplet discharging head in a direction intersecting with a moving direction of the work;
The head moving table vertically suspends the functional liquid droplet discharge head and moves the functional liquid discharge head so as to pass through a substantially intermediate position in an extending direction of the first work table and the second work table. The droplet discharge device according to claim 4, wherein: The work supply mechanism includes a supply work cassette that stores a work before processing,
A supply robot for transferring a work in the supply work cassette to the first work table and the second work table;
A supply robot moving mechanism for moving the supply robot between a position where the work is taken out from the supply work cassette, a position facing the supply position of the first work table, and a position facing the supply position of the second work table; The droplet discharge device according to claim 4, further comprising: 7. The supply work cassette and the supply robot moving mechanism are arranged in a row in a direction intersecting an extending direction of the first work table and the second work table. Droplet ejection device. The work collection mechanism includes a collection work cassette that stores the processed work,
A collection robot that transfers the work of the first work table and the second work table to the collection work cassette;
When the collection robot is moved between a position where the work is transferred to the collection work cassette, a position facing the collection position of the first work table, and a position facing the collection position of the second work table, the collection robot moves. The droplet discharge device according to any one of claims 4 to 7, further comprising a mechanism. The collection work cassette and the collection robot moving mechanism,
9. The droplet discharge device according to claim 8, wherein the droplets are arranged in a row in a direction intersecting an extending direction of the first work table and the second work table. In a work replacement method of a droplet discharge device that performs a work process by discharging a functional droplet from the functional droplet discharge head while relatively moving the functional droplet discharge head with respect to the workpiece,
Using a first work table and a second work table on each of which a work is mounted,
While the work processing is being performed by the first work table, the work after processing and the work before processing are replaced on the second work table,
A method of exchanging a workpiece in a droplet discharge device, wherein a workpiece after processing and a workpiece before processing are replaced on the first work table while the workpiece processing is being performed by the second work table. . An electro-optical device using the droplet discharge device according to claim 1, wherein a functional droplet is discharged from the functional droplet discharge head onto a workpiece to form a film forming unit. 10. An electro-optical device according to claim 1, wherein a functional droplet is ejected from the functional droplet ejection head onto a workpiece by using the droplet ejection device according to claim 1. Production method. An electronic apparatus comprising the electro-optical device according to claim 11 or an electro-optical device manufactured by the method for manufacturing an electro-optical device according to claim 12.

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